Diagnosis and treatment of arthritis using epigenetics

ABSTRACT

Embodiments of the present invention include methods, compositions and kits for evaluating a diagnosis, prognosis, or response to treatment of a subject with a disorder such as rheumatoid arthritis or osteoarthritis. Some embodiments include identifying a therapeutic agent for treating a disorder such as rheumatoid arthritis or osteoarthritis.

RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 61/530,072 entitled “DIAGNOSIS AND TREATMENT OF ARTHRITIS USING EPIGENETICS” filed on Sep. 1, 2011, which is incorporated herein by reference in its entirety.

REFERENCE TO SEQUENCE LISTING

The present application is being filed along with a Sequence Listing in electronic format. The Sequence Listing is provided as a file entitled UCSD055_(—)001A.TXT, created Aug. 24, 2012, which is approximately 135,386 KB in size. The information in the electronic format of the Sequence Listing is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

Embodiments of the present invention include methods, compositions and kits for evaluating a diagnosis, prognosis, or response to treatment of a subject with a disorder such as rheumatoid arthritis or osteoarthritis. Some embodiments include identifying a therapeutic agent for treating a disorder such as rheumatoid arthritis or osteoarthritis.

BACKGROUND OF THE INVENTION

Rheumatoid arthritis is an immune-mediated disease marked by symmetric inflammation in diarthrodial joints and destruction of the extracellular matrix. Genomics has rapidly advanced our understanding of susceptibility and severity of RA, and many associated polymorphisms in key genes have been described. However, identical twins have a concordance rate of only 12-15% suggesting that other influences can affect either the onset or progression of disease, such as epigenetic regulation of gene expression. One of the most widely studied epigenetic mechanisms, especially in oncology, is DNA methylation, which plays a key role regulating and silencing gene expression and could potentially contribute to immune dysregulation.

The pathogenesis of Rheumatoid arthritis (RA) is complex and involves numerous cell types that contribute through adaptive and innate immune responses (Firestein G S. Evolving concepts of rheumatoid arthritis. Nature, 423:356-361, 2003). Fibroblast-like synoviocytes (FLS), which form the synovial intimal lining, play an integral role by producing key cytokines (e.g., IL-6), small molecule mediators (e.g., prostanoids), and proteases (e.g., metalloproteinases). While osteoclasts are the primary effectors of bone erosions in arthritis, FLS are responsible for cartilage damage by virtue of their ability to adhere to and invade cartilage extracellular matrix. This capacity requires homotypic aggregation mediated by the adhesion molecule cadherin-11, which directs intimal lining formation and supports an invasive phenotype (Kiener H P et al. Cadherin 11 promotes invasive behavior of fibroblast-like synoviocytes. Arthritis Rheum. 2009 May; 60(5):1305-10). A well-defined relationship has long been recognized between synovial tissue histology and function and peripheral blood cell characteristics in diseases like RA, most likely because the circulating cells actively traffic between the synovium, lymph nodes, and peripheral blood (Malone D G et al. Immune function in severe, active rheumatoid arthritis. A relationship between peripheral blood mononuclear cell proliferation to soluble antigens and synovial tissue immunohistologic characteristics. J Clin Invest., 74(4):1173-1185, 1984; Firestein, G S. Etiology and pathogenesis of rheumatoid arthritis, In: Textbook of Rheumatology, G S Firestein, et al. eds., Elsevier, Philadelphia, 8th edition, 2009, pp. 1035-86). Understanding the precise molecular mechanisms that regulate FLS and peripheral blood cell activation in inflammatory arthritis could provide insights into the pathogenesis of RA and lead to novel therapeutic strategies.

SUMMARY OF THE INVENTION

Some embodiments of the methods, compositions and kits provided herein include a method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising determining whether at least 2 nucleic acid loci or at least 2 genes in a sample from said subject have methylation states indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.

Some embodiments also include comprising comparing the methylation states of the at least 2 loci or at least 2 genes in the sample from said subject with the methylation states of the loci or genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis.

In some embodiments, an increase or decrease in the extent of methylation of at least 2 loci or at least 2 genes compared to the extent of methylation of the loci or genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis is indicative of the presence or absence of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or response to treatment for rheumatoid arthritis or osteoarthritis for the subject.

In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in fibroblasts from said subject. In some embodiments, the methylation state of said at least 2 loci or at least 2 genes is determined in synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in fibroblast-like synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in rheumatoid arthritis fibroblast-like synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in osteoarthritis fibroblast-like synoviocytes from said subject.

In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in macrophage from said subject.

In some embodiments, the methylation states of said at least 2 loci or at least 2 genes are determined in peripheral blood cells from said subject. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

In some embodiments, the at least 2 loci are selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 8. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 3.

In some embodiments, the methylation states of at least 5 nucleic acid loci or at least 5 genes in said sample are determined. In some embodiments, the methylation states of at least 10 nucleic acid loci or at least 10 genes in said sample are determined. In some embodiments, the methylation states of at least 20 nucleic acid loci or at least 20 genes in said sample are determined. In some embodiments, the methylation states of at least 50 nucleic acid loci or at least 50 genes in said sample are determined. In some embodiments, the methylation states of at least 100 nucleic acid loci or at least 100 genes are determined.

In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.

In some embodiments, the nucleic acid loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the nucleic acid loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the nucleic acid loci are selected from the group consisting of the loci listed in TABLE 8.

Some embodiments of the methods, compositions and kits provided herein include a method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising determining the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample of said subject to obtain a methylation profile; and determining whether said methylation profile is indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.

Some embodiments also include comparing the methylation state of the plurality of nucleic acid loci or the methylation state of the plurality of genes in the sample from said subject with the methylation state of the plurality of nucleic acid loci or the methylation state of the plurality of genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis.

In some embodiments, an increase or decrease in the extent of methylation of plurality of nucleic acid loci or of the methylation state of the plurality of genes compared to the extent of methylation of the plurality of nucleic acid loci or the extent of methylation of the plurality of genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis is indicative of the presence or absence of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or response to treatment for rheumatoid arthritis or osteoarthritis for the subject.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in fibroblasts from said subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in synoviocytes from said subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in fibroblast-like synoviocytes from said subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in rheumatoid arthritis fibroblast-like synoviocytes from said subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in osteoarthritis fibroblast-like synoviocytes from said subject.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in macrophage from said subject.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in peripheral blood cells from said subject. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

In some embodiments, the plurality of nucleic acid loci is selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the plurality of nucleic acid loci is selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the plurality of nucleic acid loci is selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the plurality of nucleic acid loci is selected from the group consisting of the loci listed in TABLE 8.

In some embodiments, the plurality genes is selected from the group consisting of the loci listed in TABLE 3.

In some embodiments, the methylation states of at least 5 nucleic acid loci or at least 5 genes in said sample are determined. In some embodiments, the methylation states of at least 10 nucleic acid loci or at least 10 genes in said sample are determined. In some embodiments, the methylation states of at least 20 nucleic acid loci or at least 20 genes in said sample are determined. In some embodiments, the methylation states of at least 50 nucleic acid loci or at least 50 genes in said sample are determined. In some embodiments, the methylation states of at least 100 nucleic acid loci or at least 100 genes are determined.

In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.

Some embodiments of the methods, compositions and kits provided herein include a method of identifying a methylation profile indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis comprising determining the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample from a test subject with rheumatoid arthritis, osteoarthritis, a particular rheumatoid arthritis or osteoarthritis prognosis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis; determining the methylation states of said plurality of nucleic acid loci or said plurality of genes in a sample from a control subject without rheumatoid arthritis, without osteoarthritis, without said rheumatoid arthritis or osteoarthritis prognosis or without said response to treatment for rheumatoid arthritis or osteoarthritis; and identifying loci or genes which are hypermethylated or hypomethylated in said sample from said test subject relative to said sample from said control subject to identify said methylation profile indicative of rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.

Some embodiments also include storing data representing said loci or said genes which are hypermethylated or hypomethylated in said sample from said test subject relative to said sample from said control subject on a non-transitory computer readable medium.

Some embodiments also include comparing the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample from a test subject with rheumatoid arthritis, osteoarthritis, a particular rheumatoid arthritis or osteoarthritis prognosis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis with the methylation states of said plurality of nucleic acid loci or the methylation states of said plurality of genes in a sample from a control subject without rheumatoid arthritis, without osteoarthritis, without said rheumatoid arthritis or osteoarthritis prognosis or without said response to treatment for rheumatoid arthritis or osteoarthritis.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or said control subject is determined in fibroblasts from said test subject or said control subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or said control subject is determined in synoviocytes from said test subject or said control subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or control subject is determined in fibroblast-like synoviocytes from said test subject or said control subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or control subject is determined in rheumatoid arthritis fibroblast-like synoviocytes from said test subject or control subject. In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or control subject is determined in osteoarthritis fibroblast-like synoviocytes from said test subject or control subject.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or control subject is determined in macrophage from said test subject or control subject.

In some embodiments, the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or control subject is determined in peripheral blood cells from said test subject or control subject. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

In some embodiments, the methylation states of at least 5 nucleic acid loci or at least 5 genes are determined. In some embodiments, the methylation states of at least 10 nucleic acid loci or at least 10 genes are determined. In some embodiments, the methylation states of at least 20 nucleic acid loci or at least 20 genes are determined. In some embodiments, the methylation states of at least 50 nucleic acid loci or at least 50 genes are determined. In some embodiments, the methylation states of at least 100 nucleic acid loci or at least 100 genes are determined.

In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.

Some embodiments of the methods, compositions and kits provided herein include a method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising accessing first data representing the methylation status of nucleic acid loci or the methylation status of at least one gene which are differentially methylated in individuals with rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis wherein said data is stored on a non-transitory computer readable medium; instructing a computer to compare said first data to second data representing the methylation status of said nucleic acid loci or said at least one gene in a sample taken from said subject, wherein said data representing the methylation status of said nucleic acid loci or said at least one gene in a sample taken from said subject is stored on a non-transitory computer readable medium; and instructing said computer to provide an output indicating whether said comparison indicates that said subject has rheumatoid arthritis or osteoarthritis, has a positive or negative prognosis for rheumatoid arthritis or osteoarthritis prognosis, or indicates a positive or negative prediction for the subject's response to treatment for rheumatoid arthritis or osteoarthritis.

Some embodiments also include diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in said subject if said first data representing the methylation status of said nucleic acid loci or said at least one gene in a sample taken from said subject are significantly similar to said second data representing nucleic acid loci or genes which are differentially methylated in individuals with rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.

Some embodiments of the methods, compositions and kits provided herein include a method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising: determining the methylation states of at least 2 loci selected from the group consisting of SEQ ID NO.s 1-485512 in a sample obtained from the subject.

Some embodiments also include comparing the methylation states of the at least 2 loci in the sample with the methylation states of the loci in normal tissue, tissue from a subject with a known prognosis, or tissue from a subject with a known response to treatment.

In some embodiments, an increase or decrease in the extent of methylation of at least 2 loci compared to the extent of methylation of the loci in normal tissue, tissue from a subject with a known prognosis, or tissue from a subject with a known response to treatment is indicative of the presence or absence of rheumatoid arthritis, prognosis, or response to treatment for the subject.

In some embodiments, the methylation states of said at least 2 loci are determined in fibroblasts from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in fibroblast-like synoviocytes from said subject. In some embodiments, the methylations state of said at least 2 loci are determined in rheumatoid arthritis fibroblast-like synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in osteoarthritis fibroblast-like synoviocytes from said subject.

In some embodiments, the methylation states of said at least 2 loci are determined in macrophage from said subject.

In some embodiments, the methylation states of said at least 2 loci are determined in peripheral blood cells from said subject. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 8. In some embodiments, the methylation states of at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined.

In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.

Some embodiments of the methods, compositions and kits provided herein include a method for identifying a therapeutic agent for treating rheumatoid arthritis or osteoarthritis comprising contacting a cell with a test agent; and determining the methylation states in the contacted cell of at least 2 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis.

Some embodiments also include comparing the methylation states of the at least 2 loci in the contacted cell with the methylation states of the loci in a cell which was not contacted with the test agent; and selecting a test agent that increases or decreases the extent of methylation of the at least 2 loci in the cell contacted with the test agent compared to the extent of methylation of the at least 2 loci in a cell which was not contacted with the test agent such that the extent of methylation of the at least 2 loci in the cell contacted with the test agent is a methylation states associated with the absence of rheumatoid arthritis or osteoarthritis or with a reduction in the symptoms associated with rheumatoid arthritis osteoarthritis.

In some embodiments, the at least 2 loci are selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 8.

In some embodiments, the methylation states of at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined.

In some embodiments, the cell comprises a fibroblast. In some embodiments, the cell comprises a synoviocyte. In some embodiments, the cell comprises a fibroblast-like synoviocyte. In some embodiments, the cell comprises a rheumatoid arthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises an osteoarthritis fibroblast-like synoviocyte.

In some embodiments, the cell comprises a macrophage.

In some embodiments, the cell comprises a peripheral blood cell. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the cell is mammalian. In some embodiments, the cell is a human.

In some embodiments, a sample comprises the cell, the sample selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

Some embodiments of the methods, compositions and kits provided herein include a kit for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising: a reagent for determining the methylation states of at least 2 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis.

In some embodiments, the at least 2 loci are selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

Some embodiments also include at least one polynucleotide primer comprising a sequence hybridizing to at least a portion of the at least 2 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

In some embodiments, the reagent comprises a restriction enzyme.

In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the reagent can determine the methylation states of at least 5 loci selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the reagent can determine the methylation states of at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, the reagent can determine the methylation states of at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, the reagent can determine the methylation states of at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, the reagent can determine the methylation states of at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, the reagent can determine the methylation states of at least 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

Some embodiments of the methods, compositions and kits provided herein include a method for determining whether an individual suffers from rheumatoid arthritis or osteoarthritis comprising determining the methylation states of at least 2 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis, wherein the individual is diagnosed with rheumatoid arthritis if the methylation state of said at least 2 loci are associated with rheumatoid arthritis and the individual is diagnosed with osteoarthritis if the methylation states of said at least 2 loci are associated with osteoarthritis.

In some embodiments, the at least 2 loci are selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 6. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least 2 loci are selected from the group consisting of the loci listed in TABLE 8.

In some embodiments, the methylation states of at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined. In some embodiments, the methylation states of at least 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are determined.

Some embodiments of the methods, compositions and kits provided herein include a method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising: determining the methylation states of at least 2 genes selected from the group consisting of the genes listed in TABLE 3 in a sample obtained from the subject.

Some embodiments also include comparing the methylation states of the at least 2 genes in the sample with the methylation states of the genes in normal tissue, tissue from a subject with a known prognosis, or tissue from a subject with a known response to treatment.

In some embodiments, an increase or decrease in the extent of methylation of at least 2 genes compared to the extent of methylation of the of the genes in normal tissue, tissue from a subject with a known prognosis, or tissue from a subject with a known response to treatment is indicative of the presence or absence of rheumatoid arthritis, prognosis, or response to treatment for the subject.

In some embodiments, the methylation states of said at least 2 loci are determined in fibroblasts from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in fibroblast-like synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in rheumatoid arthritis fibroblast-like synoviocytes from said subject. In some embodiments, the methylation states of said at least 2 loci are determined in osteoarthritis fibroblast-like synoviocytes from said subject.

In some embodiments, the methylation states of said at least 2 loci are determined in macrophage from said subject.

In some embodiments, the methylation states of said at least 2 loci are determined in peripheral blood cells from said subject. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

In some embodiments, the methylation states of at least 5 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 10 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 20 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 50 genes selected from the group consisting of the genes listed in TABLE 3 are determined.

In some embodiments, the subject is a mammal. In some embodiments, the subject is a human.

Some embodiments of the methods, compositions and kits provided herein include a method for identifying a therapeutic agent for treating rheumatoid arthritis or osteoarthritis comprising contacting a cell with a test agent; and determining the methylation states of at least 2 genes selected from the group consisting of the genes listed in TABLE 3 in the contacted cell.

Some embodiments also include comparing the methylation states of the at least 2 genes in the contacted cell with the methylation states of the genes in a cell which was not contacted with the test agent; and selecting a test agent that increases or decreases the extent of methylation of the at least 2 genes in the cell contacted with the test agent compared to the extent of methylation of the at least 2 genes in a cell which was not contacted with the test agent such that the extent of methylation of the at least 2 genes in the cell contacted with the test agent is a methylation states associated with the absence of rheumatoid arthritis or osteoarthritis or with a reduction in the symptoms associated with rheumatoid arthritis or osteoarthritis.

In some embodiments, the methylation states of at least 5 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 10 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 20 genes selected from the group consisting of the genes listed in TABLE 3 are determined. In some embodiments, the methylation states of at least 50 genes selected from the group consisting of the genes listed in TABLE 3 are determined.

In some embodiments, the cell comprises a fibroblast. In some embodiments, the cell comprises a synoviocyte. In some embodiments, the cell comprises a fibroblast-like synoviocyte. In some embodiments, the cell comprises a rheumatoid arthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises an osteoarthritis fibroblast-like synoviocyte.

In some embodiments, the cell comprises a macrophage.

In some embodiments, the cell comprises a peripheral blood cell. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the cell is mammalian. In some embodiments, the cell is a human.

In some embodiments, a sample comprises the cell, the sample selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

Some embodiments of the methods, compositions and kits provided herein include a kit for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising: a reagent for determining the methylation states of at least 2 genes selected from the group consisting of the genes listed in TABLE 3.

Some embodiments also include at least one polynucleotide primer comprising a sequence hybridizing to at least a portion of the at least 2 genes selected from the group consisting of the genes listed in TABLE 3.

In some embodiments, the reagent comprises a restriction enzyme.

In some embodiments, the reagent can determine the methylation states of at least 5 genes selected from the group consisting of the genes listed in TABLE 3. In some embodiments, the reagent can determine the methylation states of at least 10 genes selected from the group consisting of the genes listed in TABLE 3. In some embodiments, the reagent can determine the methylation states of at least 20 genes selected from the group consisting of the genes listed in TABLE 3. In some embodiments, the reagent can determine the methylation states of at least 50 genes selected from the group consisting of the genes listed in TABLE 3.

Some embodiments of the methods, compositions and kits provided herein include a method for identifying a therapeutic agent for treating rheumatoid arthritis or osteoarthritis comprising contacting a cell with a test agent; and determining the methylation states of at least 2 genes selected from a gene encoding a protein that acts in a pathway that includes a protein encoded by a gene that is differentially methylated in a rheumatoid arthritis cell or that is differentially methylated in a osteoarthritis cell compared to a normal cell.

Some embodiments also include comparing the methylation states of the at least 2 genes in the contacted cell with the methylation states of the genes in a cell which was not contacted with the test agent; and selecting a test agent that increases or decreases the extent of methylation of the at least 2 genes in the cell contacted with the test agent compared to the extent of methylation of the at least 2 genes in a cell which was not contacted with the test agent such that the extent of methylation of the at least 2 genes in the cell contacted with the test agent are methylation states associated with the absence of rheumatoid arthritis or methylation states associated with the absence of osteoarthritis with a reduction in the symptoms associated with rheumatoid arthritis.

In some embodiments, the pathway is selected from the group consisting of the pathways listed in TABLE 5.

In some embodiments, the methylation states of at least 5 genes selected from genes encoding proteins that act in a pathway that includes a protein encoded by a gene that is differentially methylated in a rheumatoid arthritis cell compared to a normal cell or that is differentially methylated in a osteoarthritis cell compared to a normal cell. In some embodiments, the methylation states of at least 10 genes selected from genes encoding proteins that act in a pathway that includes a protein encoded by a gene that is differentially methylated in a rheumatoid arthritis cell compared to a normal cell or that is differentially methylated in a osteoarthritis cell compared to a normal cell.

In some embodiments, the cell comprises a fibroblast. In some embodiments, the cell comprises a synoviocyte. In some embodiments, the cell comprises a fibroblast-like synoviocyte. In some embodiments, the cell comprises a rheumatoid arthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises an osteoarthritis fibroblast-like synoviocyte.

In some embodiments, the cell comprises a macrophage.

In some embodiments, the cell comprises a peripheral blood cell. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the cell is mammalian. In some embodiments, the cell is a human.

In some embodiments, a sample comprises the cell, the sample selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.

Some embodiments of the methods, compositions and kits provided herein include a method for identifying therapeutic agents for treating rheumatoid arthritis or osteoarthritis comprising contacting a cell with a test agent; and determining the activity of a protein encoded by a gene differentially methylated in a rheumatoid arthritis cell or that is differentially methylated in an osteoarthritis cell compared to a normal cell.

Some embodiments also include comparing the activity of the protein in the contacted cell with the activity of the protein in a cell which was not contacted with the test agent; and selecting a test agent that increases or decreases the activity of protein in the cell contacted with the test agent compared to the activity of the protein in a cell which was not contacted with the test agent such that the activity of the protein in the cell contacted with the test agent is an activity associated with the absence of rheumatoid arthritis or an activity associated with the absence of osteoarthritis with a reduction in the symptoms associated with rheumatoid arthritis.

In some embodiments, the protein is encoded by a gene selected from the group consisting of the genes listed in TABLE 3.

In some embodiments, the cell comprises a fibroblast. In some embodiments, the cell comprises a synoviocyte. In some embodiments, the cell comprises a fibroblast-like synoviocyte. In some embodiments, the cell comprises a rheumatoid arthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises an osteoarthritis fibroblast-like synoviocyte.

In some embodiments, the cell comprises a macrophage.

In some embodiments, the cell comprises a peripheral blood cell. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, including neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.

In some embodiments, the cell is mammalian. In some embodiments, the cell is a human.

Some embodiments of the methods, compositions and kits provided herein include a method of determining the methylation status of a plurality of human nucleic acid loci comprising contacting a nucleic acid sample from a human subject with a reagent capable of providing an indication of the methylation status of said loci, wherein said loci comprise at least 5 which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis.

In some embodiments, said reagent is a restriction enzyme.

In some embodiments, said reagent is a primer.

In some embodiments, said reagent is a probe.

In some embodiments, said reagent comprises sodium bisulfate.

In some embodiments, the at least 5 loci are selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, the at least 5 loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

Some embodiments of the methods, compositions and kits provided herein include a nucleic acid array consisting essentially of nucleic acids useful for diagnosing rheumatoid arthritis or osteoarthritis, determining a prognosis of rheumatoid arthritis or osteoarthritis, or determining or predicting a response to treatment of a subject being evaluated for or suffering from rheumatoid arthritis or osteoarthritis, wherein said nucleic acids comprise at least 5 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis.

In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

Some embodiments of the methods, compositions and kits provided herein include a method of ameliorating rheumatoid arthritis or osteoarthritis comprising evaluating the methylation status of a plurality of human nucleic acid loci in a nucleic acid sample from a human subject having symptoms of rheumatoid arthritis or osteoarthritis, wherein said loci comprise at least 5 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis; and administering a treatment for rheumatoid arthritis or osteoarthritis if said at least 5 loci have a methylation status indicative of rheumatoid arthritis or osteoarthritis.

In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8.

Some embodiments of the methods, compositions and kits provided herein include a mixture comprising a plurality of human nucleic acid loci from a human subject having symptoms indicative of potential rheumatoid arthritis or osteoarthritis and a reagent capable of providing an indication of the methylation status of said loci, wherein said loci comprise at least 5 loci which have differential extents of methylation in individuals with rheumatoid arthritis or osteoarthritis relative to individuals without rheumatoid arthritis or osteoarthritis.

In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of SEQ ID NO.s 1-485512. In some embodiments, said nucleic acids comprise at least 5 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 10 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 20 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, said nucleic acids comprise at least 50 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, and TABLE 8

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts DNA methyltranserases (DNMTs) function. DNMTs transfer methyl groups from SAM to deoxycytodine. DNMT function can be affected by changes in methyl donors in the diet or by DNMT inhibitors, like 5-aza-2′-deoxycytidine (5-azaC). The analog 5-azacytidine is also incorporated into RNA and can interfere with many other cellular processes.

FIG. 2 depicts an ILLUMINA array analysis of DNA methylation in RA and OA FLS, and the hierarchical clustering and heatmap of differentially methylated loci. The methylation levels at the 1,859 significantly differentially methylated loci were used for hierarchical clustering. The clustering of the sample is shown by the dendrogram at the top and the clustering of the loci is shown by the dendrogram on the left. The methylation levels at the loci are shown in the heatmap.

FIG. 3 depicts hypomethylation of several genes in RA FLS basal expression compared to OA FLS. Gene expression was determined by PCR in 6 to 13 separate OA and RA FLS lines for 7 genes that were significantly hypomethylated (CHI3L1, COL1A1, MYEF2, ITG4A, SYNJ2, STK24, MAP3K5). As a group, expression of hypomethylated genes in RA was significantly greater than OA (P<0.01); expression of genes that were normally methylated in RA was similar to OA, e.g., AXIN, IKKE, TBK1, NANOG, POU5F1, MAP2K6, IRF3.

FIG. 4 depicts an analysis of the focal adhesion pathway, with differentially methylated genes (ECM=extracellular matrix). Differentially methylated genes are present in key locations, most notably RTK, ITGA and ITGB.

FIG. 5 depicts a Cytoscape analysis to evaluate the networks affected by differential methylation and determine the most likely targets for subsequent analysis.

FIG. 6 depicts basal expression of DNMTs. DNMT expression was examined in resting cultured FLS. Synoviocytes were isolated from RA and OA synovium at the time of total joint replacement. 4^(th) through 6^(th) passage cells were evaluated by qPCR (graph shows relative expression units using the standard curve method).

FIG. 7 depicts decreased DNMT1 gene expression after IL-1 stimulation. FLS were stimulated with IL-1 for 24 hr and DNMT expression was determined by qPCR.

FIG. 8 depicts the decrease in DNMT function in FLS in response to IL-1. FLS were stimulated with 1 ng/ml of IL-1 for 14 days and extracts were assayed using the DNMT Activity/Inhibition Assay (Active Motif Co., Carlsbad, Calif.), which is an ELISA-based method that measures methylation of a CpG-enriched DNA substrate. A significant decline in total DNMT function (p<0.05) was observed.

DETAILED DESCRIPTION

Abnormalities in DNA methylation have been implicated in autoimmunity. The mechanism of the aggressive rheumatoid phenotype is uncertain, although several studies implicate abnormal tumor suppressor gene structure and function. Differential DNA methylation might lead to altered gene expression, synoviocyte function, and peripheral blood cell function. Global DNA methylation patterns in RA FLS were evaluated and compared to FLS derived from individuals with non-inflammatory joint disease. The data show that the RA FLS display a DNA methylome signature that distinguishes them from osteoarthritis (OA) FLS, with differentially methylated genes that are critical to cell trafficking, inflammation, and cell-extracellular matrix interactions. This signature could define risk factors for developing RA or represent imprinting due to the synovial milieu. A relationship exists between the immunopathologic status of the synovial milieu and peripheral blood mononuclear cell immune function (See e.g., Malone, et al., J Clin Invest., 74(4):1173-1185, 1984; Firestein, G S. Etiology and pathogenesis of rheumatoid arthritis, In: Textbook of Rheumatology, G S Firestein, et al. eds., Elsevier, Philadelphia, 8th edition, 2009, pp. 1035-86). Peripheral blood mononuclear cells in patients with rheumatoid arthritis demonstrate global methylation abnormalities that parallel those found in cultured fibroblast-like synoviocytes, confirming that peripheral blood cells reflect synovial biology and synoviocyte function. Methylation of the IL-10 promoter has been studied in patients with RA (Fu L. H. et al., Methylation status of the IL-10 gene promoter in the peripheral blood mononuclear cells of rheumatoid arthritis patients. Yi Chuan. 2007 November; 29(11):1357-61). However, no previous data has identified patterns of specific combinations of loci or a distinctive methylome signature that can be used to diagnose RA or provide information on the potential response to therapy (Liu C C, et al. Global DNA methylation, DNMT1, and MBD2 in patients with rheumatoid arthritis. Immunol Lett. 2011; 135:96-9; Karouzakis E, et al. DNA hypomethylation in rheumatoid arthritis synovial fibroblasts. Arthritis Rheum. 2009; 60:3613-22).

Data implicating low DNA methylation in FLS is especially intriguing in the context of RA, where pathogenic FLS exhibit many features of partially transformed cells. DNMT regulation and the methylation status of FLS were examined in view of the association of DNA hypomethylation and an aggressive phenotype in cancer. As shown in this application, differences in basal RA vs. OA DNMT expression previously described were not confirmed. This may have been because conditions in the examples of this application were rigorously controlled by discontinuing methotrexate treatment up to a month before surgery. Furthermore, it was found that IL-1 significantly decreased DNMT1, DNMT3a, and DNMT3b gene expression within hours. The change in DNMT expression was accompanied by decreased DNMT function in nuclear extracts and global hypomethylation. More striking, as described in this application, an ILLUMINA methylation array study of RA and OA cells showed 100% concordance between DNA methylation patterns and the presence of RA, indicating that RA cells are imprinted with a distinctive methylation pattern that contributes to the pathogenesis of disease.

The unique pattern of DNA methylation in RA or OA, either taken in toto or when considered based on individual loci, genes, or pathways with differential methylation, has several implications. The pattern can be used for several applications, including: diagnosis of RA or OA; assessment of disease activity and prognosis of RA or OA; identification of novel therapeutic targets useful for the development of novel therapies for RA or OA; and the development of novel therapies that increase or decrease DNA methylation and alter the pattern, such as through DNMT inhibitors or activators.

Embodiments of the present invention include methods, compositions and kits for evaluating a diagnosis, prognosis, or response to treatment of a subject with a disorder such as rheumatoid arthritis or osteoarthritis. Some embodiments include identifying a therapeutic agent for treating a disorder such as rheumatoid arthritis or osteoarthritis.

Like peripheral blood mononuclear cells, rheumatoid FLS exhibit an abnormal phenotype that contributes to disease pathogenesis (Firestein, G S. Invasive fibroblast-like synoviocytes in rheumatoid arthritis: Passive responders or transformed aggressors? Arthritis Rheum 39:1781-1790, 1996). Functional studies suggest that RA FLS are imprinted in situ and maintain these features after many passages in tissue culture. For example, RA FLS, unlike OA or normal synoviocytes, adhere to and invade cartilage explants in SCID mice (Müller-Ladner U et al. Synovial fibroblasts of patients with rheumatoid arthritis attach to and invade normal human cartilage when engrafted into SCID mice. Am J. Pathol. 1996 November; 149(5):1607-15). RA FLS can grow under anchorage-independent conditions and are less susceptible to contact inhibition. Apoptosis of RA synoviocytes in situ appears to be defective, which contributes to intimal lining hyperplasia (Baier A et al. Apoptosis in rheumatoid arthritis. Curr Opin Rheumatol. 2003 May; 15(3):274-9). Data in a SCID mouse model show that RA synoviocytes can migrate from one site to another, thereby serving as a mechanism to spread the RA phenotype and cartilage damage to distant joints (Lefèvre S et al. Synovial fibroblasts spread rheumatoid arthritis to unaffected joints. Nat. Med. 2009 December; 15(12):1414-20). Despite these findings, RA FLS are not truly transformed, as they senesce in culture after 10 to 15 passages.

Several mechanisms have been implicated in the rheumatoid phenotype. For instance, resistance to apoptosis can be due, in part, to defective expression of Phosphatase and tensin homolog (PTEN) expression, high levels of sentrin, or preferential shunting of stressed cells to DNA repair rather than programmed cell death (Pap T et al. Activation of synovial fibroblasts in rheumatoid arthritis: lack of Expression of the tumour suppressor PTEN at sites of invasive growth and destruction. Arthritis Res. 2000; 2(1):59-64; Franz J K et al. Expression of sentrin, a novel antiapoptotic molecule, at sites of synovial invasion in rheumatoid arthritis. Arthritis Rheum. 2000 March; 43(3):599-607; and You X et al. PUMA-mediated apoptosis in fibroblast-like synoviocytes does not require p53. Arthritis Res Ther. 2006; 8(6):R157). Somatic mutations of regulatory genes have been identified in cultured FLS, including the p53 tumor suppressor gene (Firestein G S et al. Somatic mutations in the p53 tumor suppressor gene in rheumatoid arthritis synovium. Proc Natl Acad Sci USA, 94: 10895-10900, 1997; Igarashi H et al. TP53 mutations coincide with the ectopic expression of activation-induced cytidine deaminase in the fibroblast-like synoviocytes derived from a fraction of patients with rheumatoid arthritis. Clin Exp Immunol. 2010 Jul. 1; 161(1):71-80; Inazuka M et al. Analysis of p53 tumour suppressor gene somatic mutations in rheumatoid arthritis synovium. Rheumatology (Oxford). 2000 March; 39(3):262-6; and Rème T et al. Mutations of the p53 tumour suppressor gene in erosive rheumatoid synovial tissue. Clin Exp Immunol. 1998 February; 111(2):353-8). Similar somatic mutations have also been described in peripheral blood mononuclear cells and synovial cells, confirming that these cell populations share many structural DNA characteristics that are either caused by RA or a result of the toxic synovial microenvironment (Cannons J L, et al. HPRT-mutant T cells in the peripheral blood and synovial tissue of patients with rheumatoid arthritis. Arthritis Rheum. 1998; 41:1772-82).

The abnormal cells are more invasive and produce increased amounts of cytokines and metalloproteinases. Microdissection of rheumatoid synovium shows islands of mutant cells residing in the intimal lining that produce prodigious amount of IL-6 (Yamanishi Y et al. p53 regulates apoptosis, synovitis and joint destruction in collagen-induced arthritis. Amer J Pathol, 160:123-30, 2002). Microsatellite instability has also been identified in RA synovium, in part due to decreased DNA repair function (Lee S—H et al. Microsatellite instability and suppressed DNA repair enzyme expression in rheumatoid arthritis. J Immunol, 170:2214-20, 2003). Somatic mutations in several other genes, including mitochondrial DNA and structural proteins like vimentin, have also been reported (Bang H et al. Mutation and citrullination modifies vimentin to a novel autoantigen for rheumatoid arthritis. Arthritis Rheum. 2007 August; 56(8):2503-11; Da Sylva T R et al. Somatic mutations in the mitochondria of rheumatoid arthritis synoviocytes. Arthritis Res Ther. 2005; 7(4):R844-51). Most of these and other aggressive features appear to be result of imprinting by rheumatoid synovial environment. Thus, they serve as amplifying mechanisms that alters the natural history of disease and enhance extracellular matrix destruction and cytokine production, leading to a signature in the systemic circulation due to cellular trafficking that can be detected in peripheral blood cells, for example.

While the focus on gene sequences, mutations, and aggressive behavior has provided useful information, other mechanisms can change cell phenotype. Epigenetics, for instance, can profoundly influence cell activation and gene expression and include DNA methylation, histone modification, and microRNAs. Histone acetylation by histone acetyltransferases (HATs) can remodel chromatin and enhance gene expression while deacetylation by histone deacetylases (HDACs) has the opposite effect. The histone deacetylase HDAC1 is overexpressed in RA FLS and HDAC inhibitors decrease synoviocyte proliferation in culture and joint damage in collagen-induced arthritis (Horiuchi M et al. Expression and function of histone deacetylases in rheumatoid arthritis synovial fibroblasts. J. Rheumatol. 2009 August; 36(8):1580-9; Saouaf S J et al. Deacetylase inhibition increases regulatory T cell function and decreases incidence and severity of collagen-induced arthritis. Exp Mol Pathol. 2009; 87(2):99-104). MicroRNAs are another epigenetic mechanism that contribute to DNA accessibility and chromatin remodeling by directly targeting individual genes. Expression of some individual microRNAs like microRNA-124a, are decreased in RA compared with OA cells, leading to enhanced chemokine expression (Nakamachi Y et al. MicroRNA-124a is a key regulator of proliferation and monocyte chemoattractant protein 1 secretion in fibroblast-like synoviocytes from patients with rheumatoid arthritis. Arthritis Rheum 60:1294, 2009; Stanczyk J et al. Altered expression of microRNA-203 in rheumatoid arthritis synovial fibroblasts and its role in fibroblast activation. Arthritis Rheum. 2011 February; 63 (2): 373-81).

DNA methylation is especially relevant to RA in terms of epigenetic mechanisms by virtue of its role in neoplasia as well as embryonic growth and development. Normal ontogeny relies on a carefully orchestrated sequence of DNA methylation to repress regulatory genes by methylating cytosine in CpG islands after they have completed their programmed role in early development (Christophersen N S and Helin K. Epigenetic control of embryonic stem cell fate. J Exp Med. Oct. 25, 2010; 207(11):2287-95). Methylation abnormalities have been associated with a variety of diseases, most notably cancer where hypomethylation and renewed expression of embryonic genes can allow cells to de-differentiate and escape from normal homeostatic controls (Kulis M and Esteller M. DNA methylation and cancer. Adv Genet. 2010; 70:27-56). Hypermethylation has also been associated with certain malignancies (Ren J et al. DNA hypermethylation as a chemotherapy target. Cell Signal. Feb. 21, 2011).

DNA methyltransferases (DNMTs) are responsible for initiating and maintaining CpG methylation in the human genome by converting cytosine to methylcytosine (FIG. 1) (Turek-Plewa J and Jagodzinski P P. The role of mammalian DNA methyltransferases in the regulation of gene expression. Cell Mol Biol Lett. 2005; 10(4):631-47). In mammalian cells, DNMT1, DNMT3a, and DNMT3b are the primary enzymes responsible for CpG methylation. DNMT3a and DNMT3b mainly regulate de novo methylation while DNMT1 maintains methylation, especially during cell division. Thus, DNMT1 plays a greater role perpetuating methylation patterns in proliferating cells. Decreased DNMT expression is associated with global hypomethylation as well as suppressed methylation of individual genes that participate in malignant transformation (Shukla V et al. BRCA1 affects global DNA methylation through regulation of DNMT1. Cell Res. 2010 November; 20(11):1201-15). DNMT expression and DNA methylation is not fixed but can be influenced by the environment and modify gene expression throughout life. The DNMTs can also maintain the methylation pattern during cell division, thereby allowing daughter cells to reflect the environmental influences of the parent cells.

DNMTs can also permit vertical transmission of parental DNA methylation (Ko Y G et al. Stage-by-stage change in DNA methylation status of Dnmt1 locus during mouse early development. J Biol. Chem. 2005 Mar. 11; 280(10):9627-34). This process allows relatively rapid responses to environmental stress that can persist over many cell divisions and even across generations (Rosenfeld. Animal models to study environmental epigenetics. Biol Reprod. 2010, 82:473-88; Kaati G et al. Transgenerational response to nutrition, early life circumstances and longevity. Eur J Hum Genet. 2007 July; 15(7):784-90). For instance, pregnant mice fed a diet rich in methyl donors like folate have increased levels of DNA methylation for at least 2 subsequent generations. Methylation of the Runx3 gene, in particular, is increased by the high methyl donor diet and leads to enhanced Th2 lymphocyte differentiation and increased airway reactivity in murine asthma (Hollingsworth J W et al. In utero supplementation with methyl donors enhances allergic airway disease in mice. J Clin Invest. 2008 October; 118(10):3462-9). Increased disease severity and airway remodeling can even be observed in F2 progeny and demonstrates how the environment can have multigenerational effects (Miller R L. Prenatal maternal diet affects asthma risk in offspring. J Clin Invest. 2008. 118:3265-8).

Abnormalities in DNA methylation have been implicated in autoimmunity. In addition to the murine model of airway disease, T cells can be affected by DNA methylation and influence Th2 differentiation (Gamper C J et al. Identification of DNA methyltransferase 3a as a T cell receptor-induced regulator of Th1 and Th2 differentiation. J Immunol. 2009 Aug. 15; 183(4):2267-76). The DNMT inhibitor 5′-aza-2′-deoxycytidine (5-azaC) (Fandy T E. Development of DNA methyltransferase inhibitors for the treatment of neoplastic diseases. Curr Med. Chem. 2009; 16(17):2075-85) affects expression of many T cell genes, including IFNα, IL-4, CD70, and LFA-1. 5-azaC enhances autoreactivity and induces robust responses to normally sub-threshold stimulation (Richardson B. DNA methylation and autoimmune disease. Clin Immunol. 2003 October; 109(1):72-9). T and B cell interactions are also affected, in part due to altered expression of surface receptors like CD70 (Oelke K et al. Overexpression of CD70 and overstimulation of IgG synthesis by lupus T cells and T cells treated with DNA methylation inhibitors. Arthritis Rheum. 2004 June; 50(6):1850-60). Decreased DNA methylation in Th1 and Th2 cell genomic DNA is also associated with production of anti-dsDNA antibodies in vivo (Richardson B et al. Murine models of lupus induced by hypomethylated T cells. Methods Mol Med. 2004; 102:285-94). Hypomethylation has been described in peripheral blood mononuclear cells in patients with RA (Liu C C et al. Global DNA methylation, DNMT1, and MBD2 in patients with rheumatoid arthritis. Immunol Lett. Mar. 30, 2011; 135(1-2):96-9. Epub Oct. 16, 2010). Despite some evidence of abnormal global methylation, there is no information on specific loci, patterns of loci, genes, or pathways that are abnormally methylated in rheumatoid arthritis.

Evidence of hypomethylation is not restricted to adaptive immunity in rheumatic disease. Like peripheral blood cells, global genomic hypomethylation was recently reported in RA cultured fibroblast-like synoviocytes (FLS) compared with Osteoarthritis (OA) FLS (Karouzakis E et al. DNA hypomethylation in rheumatoid arthritis synovial fibroblasts. Arthritis Rheum. 2009 December; 60(12):3613-22). This observation was associated with relatively low levels of DNMT1 gene expression that were unaffected by in vitro stimulation with IL-1 or TNF. DNMT3a or DNMT3b were not examined, and no studies were performed to determine whether DNMT function was abnormal. Culturing FLS in the presence of 5-azaC for 3 months to block DNA methylation increased expression of several genes implicated in RA. However, it is not certain which genes were hypomethylated and which ones were affected secondary to decreased methylation of other regulatory genes.

DNMT regulation and the methylation status of FLS were examined in view of the association of DNA hypomethylation and an aggressive phenotype in cancer. As shown in this application, it was found that IL-1 significantly decreased DNMT1, DNMT3a, and DNMT3b gene expression within hours. The change in DNMT expression was accompanied by decreased DNMT function in nuclear extracts and global hypomethylation. More striking, an ILLUMINA methylation array study of RA and OA cells showed 100% concordance between DNA methylation patterns and the presence of RA.

The unique patterns of DNA methylation in RA or OA have several implications. The patterns can be used for several applications, including: diagnosis of RA or OA; assessment of disease activity and prognosis of RA or OA; identification of novel therapeutic targets useful for the development of novel therapies for RA or OA; and the development of novel therapies that increase or decrease DNA methylation and alter the pattern, such as though DNMT inhibitors or activators.

DEFINITIONS

As used herein, “methylation” refers to cytosine methylation at positions C5 or N4 of cytosine, the N6 position of adenine or other types of nucleic acid methylation. In particular embodiments, “methylation” refers to cytosine methylation at positions C5 of cytosine, namely, 5-methly cytosine. In vitro amplified DNA is unmethylated because in vitro DNA amplification methods do not retain the methylation pattern of the amplification template. However, “unmethylated DNA” or “methylated DNA” can also refer to amplified DNA whose original template was unmethylated or methylated, respectively.

A “methylation profile” refers to a set of data representing the methylation states of two or more loci within a molecule of DNA from e.g., the genome of an individual or cells or tissues from an individual. The profile can indicate the methylation state of every cytosine base in an individual, can comprise information regarding a subset of the base pairs (e.g., the methylation state of specific restriction enzyme recognition sequence) in a genome, or can comprise information regarding regional methylation density of each locus.

As used herein, “methylation status” refers to the presence, absence and/or quantity of methylation at a particular nucleotide, or nucleotides within a portion of DNA. Determination of the methylation status of a particular DNA sequence (e.g., a locus, a DNA biomarker or DNA region as described herein) can involve determination of the methylation state of every cytosine in the sequence or can involve determination of the methylation state of a subset of the cytosines (such as the methylation state of cytosines in one or more specific restriction enzyme recognition sequences) within the sequence, or can involve determining regional methylation density within the sequence without providing precise information of where in the sequence the methylation occurs. The methylation status can optionally be represented or indicated by a “methylation value.” A methylation value can be generated, for example, by quantifying the amount of intact DNA present following restriction digestion with a methylation dependent restriction enzyme. In this example, if a particular sequence in the DNA is quantified using quantitative PCR, an amount of template DNA approximately equal to a mock treated control indicates the sequence is not highly methylated whereas an amount of template substantially less than occurs in the mock treated sample indicates the presence of methylated DNA at the sequence. Accordingly, a value, i.e., a methylation value, for example from the above described example, represents the methylation status and can thus be used as a quantitative indicator of methylation status. This is of particular use when it is desirable to compare the methylation status of a sequence in a sample to a threshold value.

As used herein, “methylation-dependent restriction enzyme” refers to a restriction enzyme that cleaves or digests DNA at or in proximity to a methylated recognition sequence, but does not cleave DNA at or near the same sequence when the recognition sequence is not methylated. Methylation-dependent restriction enzymes include those that cut at a methylated recognition sequence (e.g., DpnI) and enzymes that cut at a sequence near but not at the recognition sequence (e.g., McrBC). For example, McrBC's recognition sequence is 5′ RmC(N40-3000) RmC 3′ where “R” is a purine and “mC” is a methylated cytosine and “N40-3000” indicates the distance between the two RmC half sites for which a restriction event has been observed. McrBC generally cuts close to one half-site or the other, but cleavage positions are typically distributed over several base pairs, approximately 30 base pairs from the methylated base. McrBC sometimes cuts 3′ of both half sites, sometimes 5′ of both half sites, and sometimes between the two sites. Exemplary methylation-dependent restriction enzymes include, e.g., McrBC (see, e.g., U.S. Pat. No. 5,405,760), McrA, MrrA, BisI, GlaI and DpnI. One of skill in the art will appreciate that any methylation-dependent restriction enzyme, including homologs and orthologs of the restriction enzymes described herein, is also suitable for use in the present embodiments.

As used herein, “methylation-sensitive restriction enzyme” refers to a restriction enzyme that cleaves DNA at or in proximity to an unmethylated recognition sequence but does not cleave at or in proximity to the same sequence when the recognition sequence is methylated. Exemplary methylation-sensitive restriction enzymes are described in, e.g., McClelland et al., Nucleic Acids Res. 22(17):3640-59 (1994) and http://rebase.neb.com. Suitable methylation-sensitive restriction enzymes that do not cleave DNA at or near their recognition sequence when a cytosine within the recognition sequence is methylated at position C5 include, e.g., Aat I I, Aci I, Acd I, Age I, Alu I, Asc I, Ase I, AsiS I, Bbe I, BsaA I, BsaH I, BsiE I, BsiW I, BsrF I, BssH II, BssK I, BstB I, BstN I, BstU I, Cla I, Eae I, Eag I, Fau I, Fse I, Hha I, HinP1 I, HinC II, Hpa II, Hpy99 I, HpyCH4 IV, Kas I, Mbo I, Mlu I, MapA1 I, Msp I, Nae I, Nar I, Not I, Pml I, Pst I, Pvu I, Rsr II, Sac II, Sap I, Sau3A I, Sfl I, Sfo I, SgrA I, Sma I, SnaB I, Tsc I, Xma I, and Zra I. Suitable methylation-sensitive restriction enzymes that do not cleave DNA at or near their recognition sequence when an adenosine within the recognition sequence is methylated at position N6 include, e.g., Mbo I. One of skill in the art will appreciate that any methylation-sensitive restriction enzyme, including homologs and orthologs of the restriction enzymes described herein, is also suitable for use in the present invention. One of skill in the art will further appreciate that a methylation-sensitive restriction enzyme that fails to cut in the presence of methylation of a cytosine at or near its recognition sequence may be insensitive to the presence of methylation of an adenosine at or near its recognition sequence. Likewise, a methylation-sensitive restriction enzyme that fails to cut in the presence of methylation of an adenosine at or near its recognition sequence may be insensitive to the presence of methylation of a cytosine at or near its recognition sequence. For example, Sau3AI is sensitive (i.e., fails to cut) to the presence of a methylated cytosine at or near its recognition sequence, but is insensitive (i.e., cuts) to the presence of a methylated adenosine at or near its recognition sequence. One of skill in the art will also appreciate that some methylation-sensitive restriction enzymes are blocked by methylation of bases on one or both strands of DNA encompassing of their recognition sequence, while other methylation-sensitive restriction enzymes are blocked only by methylation on both strands, but can cut if a recognition site is hemi-methylated.

Evaluating a Diagnosis, Prognosis, or Response to Treatment

Some embodiments provided herein relate to methods for diagnosing, determining a prognosis, or determining or predicting a response to treatment. As used herein, diagnosing can include determining whether a methylation status of 1 or more loci is indicative of a disorder, such as rheumatoid arthritis. As used herein, determining a prognosis can include determining whether methylation status of 1 or more loci is indicative of a likelihood of improvement in symptoms of a disorder, such as rheumatoid arthritis. As used herein, determining or predicting a response to treatment can include determining whether methylation status of 1 or more loci after treatment is more similar to a normal status before treatment or earlier in the treatment regimen. In some embodiments of the methods and compositions provided herein, the 1 or more locus or 1 or more gene is a locus or gene with no known association with RA.

In some such embodiments, the methylation state of at least 1 locus or at least one gene selected from a locus or gene described herein in a sample obtained from a subject is determined. Examples of loci for which the methylation state may be evaluated include the loci listed in TABLE 6, TABLE 7, and TABLE 8. In some embodiments, loci for which the methylation state may be evaluated include SEQ ID NO.s:1-485512. In each sequence provided in SEQ ID NO.s 1-485512, the “C” which is potentially methylated is at position 61. Examples of genes for which the methylation state may be evaluated include the loci listed in TABLE 3. The nucleic acid sequences of the loci listed in TABLE 6, TABLE 7, and TABLE 8 and the genes listed in TABLE 3 are incorporated herein by reference. In some embodiments, additional loci and genes useful for the methods and compositions provided herein can be further identified using the methods described herein. In some embodiments, additional loci and genes useful for the methods and compositions provided herein are identified by conducting methylation analyses in additional samples, thereby providing an increased number of data points which could assist in the identification of further genes or loci having statistically significant differences in their methylation states. The sample can comprise an in vivo sample, an in vitro sample, or an ex vivo sample. It will be understood, that in some embodiments of the compositions or methods provided herein, a sample or cell can be in vivo. In some embodiments of the compositions or methods provided herein, a sample or cell can be ex vivo. Methods to determine the methylation state of at least one locus or at least one gene are well known in the art and examples are provided herein. In some embodiments, the subject is a mammal, such as a human. In some embodiments, the methylation states of at least about 1, 2, 3, 4, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300, 400, 500 loci or more than 500 loci are determined. Some embodiments also include comparing the methylation state of the at least 1 locus in the sample with the methylation state of the locus in a normal cell, cell from a subject with a known prognosis, or cell from a subject with a known response to treatment. In some embodiments, the methylation states of at least about 1, 2, 3, 4, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300, 400, 500 genes or more than 500 genes are determined. Some embodiments also include comparing the methylation state of the at least 1 gene in the sample with the methylation state of the gene in a normal cell, cell from a subject with a known prognosis, or cell from a subject with a known response to treatment.

In some embodiments, an increase or decrease in the methylation state of the at least 1 locus compared to the methylation state of the locus in normal cell, cell from a subject with a known prognosis, or cell from a subject with a known response to treatment is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, an increase or decrease in the methylation state of a locus selected from the group consisting of the loci listed in TABLE 6 is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, an increase or decrease in the methylation state of a locus selected from the group consisting of the loci listed in TABLE 7 is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, an increase or decrease in the methylation state of a locus selected from the group consisting of the loci listed in TABLE 8 is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, an increase or decrease in the methylation state of the at least 1 gene compared to the methylation state of the gene in a normal cell, cell from a subject with a known prognosis, or tissue from a subject with a known response to treatment is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, an increase or decrease in the methylation state of a gene selected from the group consisting of the genes listed in TABLE 3 is indicative of the diagnosis, prognosis, or response to treatment for the subject. In some embodiments, the increase or decrease in methylation occurs in a cell, such as a synoviocyte, such as a fibroblast-like synoviocyte, for example, a rheumatoid arthritis fibroblast-like synoviocyte or an osteoarthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises macrophage. In some embodiments, the cell comprises a peripheral blood cell. As used herein, ‘peripheral blood cell’ can include a cellular component of blood which contains DNA. Examples of peripheral blood cells include white blood cells, including neutrophils, eosinophils, basophils, lymphocytes, B cell, plasma cells, T cells, natural killer cells, monocytes, and dendritic cells. In some embodiments, the cell is mammalian, e.g., human. In some embodiments, the loci and genes which are differentially methylated in fibroblast-like synoviocytes from individuals with rheumatoid arthritis or osteoarthritis and the loci and genes which are differentially methylated in individuals with rheumatoid or osteoarthritis in cell types other than fibroblast-like synoviocytes may partially overlap. However, it is likely that there will be loci and genes which exhibit differential methylation in individuals with rheumatoid arthritis or osteoarthritis in one cell type which are not differentially methylated in other cell types from individuals with rheumatoid arthritis or osteoarthritis. Such differences in differential methylation may be a reflection of the fact that methylation patterns vary among different cell lineages. For example, differentially methylated loci and genes identified in T cells and in B cells types from individuals with rheumatoid arthritis or osteoarthritis can include loci and genes that are different in each cell type. Differentially methylated loci and genes in different cell types from individuals with rheumatoid arthritis or osteoarthritis can be identified using the methods described herein.

Some embodiments include methods of ameliorating rheumatoid arthritis or osteoarthritis in a subject. Some such embodiments include evaluating the methylation status of a plurality of human nucleic acid loci in a nucleic acid sample from a human subject having symptoms of rheumatoid arthritis or osteoarthritis. In some embodiments, the loci comprise at least about 5 loci, at least about 10 loci, at least about 15 loci, at least about 20 loci, at least about 25 loci, at least about 50 loci, and at least about 100 loci. In some embodiments the loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the loci may be selected from SEQ ID NO.s:1-485512. Some embodiments also include administering a treatment for rheumatoid arthritis or osteoarthritis if the loci have a methylation status indicative of rheumatoid arthritis or osteoarthritis.

Some embodiments include a mixture comprising a plurality of human nucleic acid loci from a human subject having symptoms indicative of potential rheumatoid arthritis or osteoarthritis and a reagent capable of providing an indication of the methylation status of said loci. In some embodiments, the loci comprise at least about 5 loci, at least about 10 loci, at least about 15 loci, at least about 20 loci, at least about 25 loci, at least about 50 loci, and at least about 100 loci. In some embodiments the loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the loci are selected from SEQ ID NO.s:1-485512

Methods to Determine Methylation State of a Locus

In some embodiments, the methylation state of more than one DNA region, e.g., gene, locus or portion thereof is determined. In some embodiments, the methylation status of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97 or more than 97 of the DNA regions is determined.

In some embodiments, the methylation state of a DNA region or portion thereof is determined and then normalized (e.g., compared) to the methylation state of a control locus. Typically the control locus will have a known, relatively constant, methylation status. For example, the control sequence can be previously determined to have no, some or a high amount of methylation, thereby providing a relative constant value to control for error in detection methods, etc., unrelated to the presence or absence of a disorder. In some embodiments, the control locus is endogenous, i.e., is part of the genome of the individual sampled. For example, in mammalian cells, the testes-specific histone 2B gene (hTH2B in human) gene is known to be methylated in all somatic tissues except testes. Alternatively, the control locus can be an exogenous locus, i.e., a DNA sequence spiked into the sample in a known quantity and having a known methylation status.

A DNA region comprises a nucleic acid including one or more methylation sites of interest (e.g., a cytosine, a “microarray feature,” or an amplicon amplified from select primers) and flanking nucleic acid sequences (i.e., “wingspan”) of up to 4 kilobases (kb) in either or both of the 3′ or 5′ direction from the amplicon. This range corresponds to the lengths of DNA fragments obtained by randomly fragmenting the DNA before screening for differential methylation between DNA in two or more samples (e.g., carrying out methods used to initially identify differentially methylated loci). In some embodiments, the wingspan of the one or more DNA regions is about 0.5 kb, 0.75 kb, 1.0 kb, 1.5 kb, 2.0 kb, 2.5 kb, 3.0 kb, 3.5 kb or 4.0 kb in both 3′ and 5′ directions relative to the sequence represented by the microarray feature. The DNA region of interest can comprise and/or be immediately adjacent to a locus selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8, or a gene selected from a gene listed in TABLE 3. In some embodiments, the locus may be selected from SEQ ID NO.s:1-485512. The nucleic acid sequences of the loci listed in TABLE 6, TABLE 7, and TABLE 8 are available, for example, in the Illumina CpG database, and included in SEQ ID NO.s:1-485512.

The methylation sites in a DNA region can reside in non-coding transcriptional control sequences (e.g., promoters, enhancers, etc.) or in coding sequences, including introns and exons of the loci listed in TABLE 6, TABLE 7, or TABLE 8, and genes listed in TABLE 3. In some embodiments, the methods comprise detecting the methylation status in the promoter regions (e.g., comprising the nucleic acid sequence that is about 1.0 kb, 1.5 kb, 2.0 kb, 2.5 kb, 3.0 kb, 3.5 kb or 4.0 kb 5′ from the transcriptional start site through to the translational start site) of one or more of the locus identified in TABLE 6, TABLE 7, TABLE 8, or TABLE 3. In some embodiments, the locus may be selected from SEQ ID NO.s:1-485512.

Any method for detecting DNA methylation can be used in the methods provided herein. In some embodiments, an array can be used to determine the methylation state of at least one locus, such as the ILLUMINA HumanMethylation 450 BeadChip. DNA is treated with bisulfite to convert unmethylated cytosines to uracil, methylated cytosines are protected and remain cytosine. After the conversion step, a determination step is performed to identify whether a base at a particular locus was converted. Methylation status of the interrogated site is calculated as the ratio of the signal from a methylated probe relative to the sum of both methylated and unmethlylated probes. This value, known as β, ranges continuously from 0 (unmethlylated) to 1 (fully methylated). Arrays, such as the ILLUMINA HumanMethylation 450 BeadChip, include genes and CpG islands and other sequences.

In some embodiments, methods for detecting methylation include randomly shearing or randomly fragmenting the genomic DNA, cutting the DNA with a methylation-dependent or methylation-sensitive restriction enzyme and subsequently selectively identifying and/or analyzing the cut or uncut DNA. Selective identification can include, for example, separating cut and uncut DNA (e.g., by size) and quantifying a sequence of interest that was cut or, alternatively, that was not cut. See, e.g., U.S. Pat. No. 7,186,512. Alternatively, the method can encompass amplifying intact DNA after restriction enzyme digestion, thereby only amplifying DNA that was not cleaved by the restriction enzyme in the area amplified. See, e.g., U.S. patent application Ser. Nos. 10/971,986; 11/071,013; and 10/971,339. In some embodiments, amplification can be performed using primers that are gene specific. Alternatively, adaptors can be added to the ends of the randomly fragmented DNA, the DNA can be digested with a methylation-dependent or methylation-sensitive restriction enzyme, intact DNA can be amplified using primers that hybridize to the adaptor sequences. In this case, a second step can be performed to determine the presence, absence or quantity of a particular gene in an amplified pool of DNA. In some embodiments, the DNA is amplified using real-time, quantitative PCR.

In some embodiments, the methods comprise quantifying the average methylation density in a target sequence within a population of genomic DNA. In some embodiments, the method comprises contacting genomic DNA with a methylation-dependent restriction enzyme or methylation-sensitive restriction enzyme under conditions that allow for at least some copies of potential restriction enzyme cleavage sites in the locus to remain uncleaved; quantifying intact copies of the locus; and comparing the quantity of amplified product to a control value representing the quantity of methylation of control DNA, thereby quantifying the average methylation density in the locus compared to the methylation density of the control DNA.

The quantity of methylation of a locus of DNA can be determined by providing a sample of genomic DNA comprising the locus, cleaving the DNA with a restriction enzyme that is either methylation-sensitive or methylation-dependent, and then quantifying the amount of intact DNA or quantifying the amount of cut DNA at the DNA locus of interest. The amount of intact or cut DNA will depend on the initial amount of genomic DNA containing the locus, the amount of methylation in the locus, and the number (i.e., the fraction) of nucleotides in the locus that are methylated in the genomic DNA. The amount of methylation in a DNA locus can be determined by comparing the quantity of intact DNA or cut DNA to a control value representing the quantity of intact DNA or cut DNA in a similarly-treated DNA sample. The control value can represent a known or predicted number of methylated nucleotides. Alternatively, the control value can represent the quantity of intact or cut DNA from the same locus in another (e.g., normal, non-diseased) cell or a second locus.

By using at least one methylation-sensitive or methylation-dependent restriction enzyme under conditions that allow for at least some copies of potential restriction enzyme cleavage sites in the locus to remain uncleaved and subsequently quantifying the remaining intact copies and comparing the quantity to a control, average methylation density of a locus can be determined. As used herein, ‘methylation density’ can refer to the number of methylated C-residues within a region. If the methylation-sensitive restriction enzyme is contacted to copies of a DNA locus under conditions that allow for at least some copies of potential restriction enzyme cleavage sites in the locus to remain uncleaved, then the remaining intact DNA will be directly proportional to the methylation density, and thus may be compared to a control to determine the relative methylation density of the locus in the sample. Similarly, if a methylation-dependent restriction enzyme is contacted to copies of a DNA locus under conditions that allow for at least some copies of potential restriction enzyme cleavage sites in the locus to remain uncleaved, then the remaining intact DNA will be inversely proportional to the methylation density, and thus may be compared to a control to determine the relative methylation density of the locus in the sample. Such assays are disclosed in, e.g., U.S. patent application Ser. No. 10/971,986.

Quantitative amplification methods (e.g., quantitative PCR or quantitative linear amplification) can be used to quantify the amount of intact DNA within a locus flanked by amplification primers following restriction digestion. Methods of quantitative amplification are disclosed in, e.g., U.S. Pat. Nos. 6,180,349; 6,033,854; and 5,972,602, as well as in, e.g., Gibson et al., Genome Research 6:995-1001 (1996); DeGraves, et al., Biotechniques 34(1):106-10, 112-5 (2003); Deiman B, et al., Mol. Biotechnol. 20(2):163-79 (2002). Amplifications may be monitored in “real time.”

Additional methods for detecting DNA methylation can involve genomic sequencing before and after treatment of the DNA with bisulfite. See, e.g., Frommer et al., Proc. Natl. Acad. Sci. USA 89:1827-1831 (1992). When sodium bisulfite is contacted to DNA, unmethylated cytosine is converted to uracil, while methylated cytosine is not modified.

In some embodiments, restriction enzyme digestion of PCR products amplified from bisulfite-converted DNA is used to detect DNA methylation. See, e.g., Sadri & Hornsby, Nucl. Acids Res. 24:5058-5059 (1996); Xiong & Laird, Nucleic Acids Res. 25:2532-2534 (1997).

In some embodiments, a MethyLight assay is used alone or in combination with other methods to detect DNA methylation (see, Eads et al., Cancer Res. 59:2302-2306 (1999)). Briefly, in the MethyLight process genomic DNA is converted in a sodium bisulfite reaction (the bisulfite process converts unmethylated cytosine residues to uracil). Amplification of a DNA sequence of interest is then performed using PCR primers that hybridize to CpG dinucleotides. By using primers that hybridize only to sequences resulting from bisulfite conversion of unmethylated DNA, (or alternatively to methylated sequences that are not converted) amplification can indicate methylation status of sequences where the primers hybridize. Similarly, the amplification product can be detected with a probe that specifically binds to a sequence resulting from bisulfite treatment of a unmethylated (or methylated) DNA. If desired, both primers and probes can be used to detect methylation status. Thus, kits for use with MethyLight can include sodium bisulfite as well as primers or detectably-labeled probes (including but not limited to Taqman or molecular beacon probes) that distinguish between methylated and unmethylated DNA that have been treated with bisulfite. Other kit components can include, e.g., reagents necessary for amplification of DNA including but not limited to, PCR buffers, deoxynucleotides; and a thermostable polymerase.

In some embodiments, a Ms-SNuPE (Methylation-sensitive Single Nucleotide Primer Extension) reaction is used alone or in combination with other methods to detect DNA methylation (see, Gonzalgo & Jones, Nucleic Acids Res. 25:2529-2531 (1997)). The Ms-SNuPE technique is a quantitative method for assessing methylation differences at specific CpG sites based on bisulfite treatment of DNA, followed by single-nucleotide primer extension (Gonzalgo & Jones, supra). Briefly, genomic DNA is reacted with sodium bisulfite to convert unmethylated cytosine to uracil while leaving 5-methylcytosine unchanged. Amplification of the desired target sequence is then performed using PCR primers specific for bisulfite-converted DNA, and the resulting product is isolated and used as a template for methylation analysis at the CpG site(s) of interest.

Typical reagents (e.g., as might be found in a typical Ms-SNuPE-based kit) for Ms-SNuPE analysis can include, but are not limited to: PCR primers for specific gene (or methylation-altered DNA sequence or CpG island); optimized PCR buffers and deoxynucleotides; gel extraction kit; positive control primers; Ms-SNuPE primers for a specific gene; reaction buffer (for the Ms-SNuPE reaction); and detectably-labeled nucleotides. Additionally, bisulfite conversion reagents may include: DNA denaturation buffer; sulfonation buffer; DNA recovery regents or kit (e.g., precipitation, ultrafiltration, affinity column); desulfonation buffer; and DNA recovery components.

In some embodiments, a methylation-specific PCR (“MSP”) reaction is used alone or in combination with other methods to detect DNA methylation. An MSP assay entails initial modification of DNA by sodium bisulfite, converting all unmethylated, but not methylated, cytosines to uracil, and subsequent amplification with primers specific for methylated versus unmethylated DNA. See, Herman et al., Proc. Natl. Acad. Sci. USA 93:9821-9826, (1996); U.S. Pat. No. 5,786,146.

Additional methylation detection methods include, but are not limited to, methylated CpG island amplification (see, Toyota et al., Cancer Res. 59:2307-12 (1999)) and those described in, e.g., U.S. Patent Publication 2005/0069879; Rein, et al. Nucleic Acids Res. 26 (10): 2255-64 (1998); Olek, et al. Nat. Genet. 17(3): 275-6 (1997); and PCT Publication No. WO 00/70090.

Some embodiments provided herein include methods of determining the methylation status of a plurality of human nucleic acid loci. Some such embodiments include contacting a nucleic acid sample from a human subject with a reagent capable of providing an indication of the methylation status of said loci. In some embodiments, the loci comprise at least about 5 loci, at least about 10 loci, at least about 15 loci, at least about 20 loci, at least about 25 loci, at least about 50 loci, and at least about 100 loci. In some embodiments the loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the reagent is a restriction enzyme. In some embodiments, the reagent is a primer. In some embodiments, the reagent is a probe. In some embodiments, the reagent comprises sodium bisulfite.

Identifying Therapeutic Agents

Some embodiments provided herein relate to methods for identifying therapeutic agents. Some such embodiments for identifying therapeutic agents which may be used to treat rheumatoid arthritis or osteoarthritis, can include contacting a cell with a test agent; and determining the methylation state of at least 1 locus selected from the loci listed in TABLE 6, TABLE 7, or TABLE 8 or at least one gene listed in Table 3 in the contacted cell. In some embodiments, the at least one locus may be selected from SEQ ID NO.s:1-485512. Some methods also include comparing the methylation state of the at least 1 locus, or at least 1 gene in the contacted cell with the methylation state of the locus or the gene in the cell not contacted with the test agent, and selecting a test agent that increases or decreases the methylation state of the at least 1 locus or the at least 1 gene in the cell contacted with the test agent compared to the methylation state of the locus or the gene in a cell not contacted with the test agent. For example, if a locus, a gene group of loci or group of genes are hypermethylated in individuals with RA, agents which reduce the level of methylation at the locus, the gene, group of loci or group of genes may be useful as therapeutic agents. Likewise, if a locus, a gene, group of loci or group of genes are hypomethylated in individuals with RA, agents which increase the level of methylation at the locus, the gene group of loci or group of genes may be useful as therapeutic agents. Likewise, agents which produce a methylation profile in cells contacted with the agent having a greater similarity to the methylation profile of individuals who do not suffer from RA relative to the methylation profile in cells which have not been contacted with the agent may be useful as therapeutic agents. Examples of test agents and potential therapeutic agents include small molecules (including but not limited to organic chemical compounds which have been obtained from natural sources or synthesized), nucleic acids (including but not limited to antisense nucleic acids, ribozymes, or siRNAs), peptides and proteins (including but not limited to cytokines TNF-α, and DMNTs).

In some embodiments, at least 1 locus is selected from the group consisting of the loci listed in TABLE 6. In some embodiments, at least 1 locus is selected from the group consisting of the loci listed in TABLE 7. In some embodiments, the at least one locus may be selected from SEQ ID NO.s:1-485512. In some embodiments, at least 1 gene is selected from the group consisting of the gene listed in TABLE 3.

In some embodiments, the methylation states of at least about 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, or 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8 are determined. In some embodiments, the methylation states of at least about 5, 10, 20, 30, 40, 50, 60, 70, 80, or 100 loci selected from the group consisting of the loci of SEQ ID NO.s:1-485512. In some embodiments, the methylation states of at least about 1, 5, 10, 20, 30, 40, 50 genes selected from the group consisting of the genes listed in TABLE 3 are determined

In some embodiments, the cell comprises a synoviocyte, such as a fibroblast-like synoviocyte, for example, a rheumatoid arthritis fibroblast-like synoviocyte or an osteoarthritis fibroblast-like synoviocyte. In some embodiments, the cell comprises a macrophage. In some embodiments, the cell comprises a peripheral blood cell. In some embodiments, the peripheral blood cell is selected from the group consisting of white blood cell, including neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell. In some embodiments, the cell is mammalian, e.g., human.

More embodiments of methods for identifying therapeutic reagents include identifying agents that modulate methylation of genes encoding proteins that act in the same pathway as other proteins encoded by genes that are differentially methylated in rheumatoid arthritis or osteoarthritis or agents which modulate the activity of proteins in the same pathway as proteins encoded by genes which are differentially methylated in rheumatoid arthritis or osteoarthritis. Some methods for identifying a therapeutic agent for treating rheumatoid arthritis or osteoarthritis include contacting a cell with a test agent, and determining the methylation state of at least 1 gene selected from a gene encoding a protein that acts in a pathway that includes a protein encoded by a gene that is differentially methylated in a rheumatoid arthritis cell or osteoarthritis cell compared to a normal cell. Some methods also include comparing the methylation state of the at least 1 gene in the contacted cell with the methylation state of the gene in a cell which was not contacted with the test agent, selecting a test agent that increases or decreases the extent of methylation of the at least 1 gene in the cell contacted with the test agent compared to the extent of methylation of the at least 1 gene in a cell which was not contacted with the test agent such that the extent of methylation of the at least 1 gene in the cell contacted with the test agent is a methylation state associated with the absence of rheumatoid arthritis or osteoarthritis or with a reduction in the symptoms associated with rheumatoid arthritis or osteoarthrities. In some embodiments, the pathway is selected from focal adhesion, glycosphingolipid biosynthesis—lacto and neolacto series, arrhythmogenic right ventricular cardiomyopathy (ARVC), ECM-receptor interaction, amoebiasis, leukocyte transendothelial migration, protein digestion and absorption, cell adhesion molecules (CAMs), nitrogen metabolism, ErbB signaling pathway, African trypanosomiasis, primary bile acid biosynthesis, Fc epsilon RI signaling pathway, mTOR signaling pathway, and adipocytokine signaling pathway.

Kits

Some embodiments provided herein relate to kits. Some such kits can be useful for diagnosing, determining a prognosis, or determining a response to treatment of a subject with a disorder, such as rheumatoid arthritis, comprising: a reagent for determining the methylation state of at least one locus selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the at least one locus may be selected from SEQ ID NO.s:1-485512. In some embodiments, the kit also includes at least one polynucleotide primer comprising a sequence hybridizing to at least a portion of the at least one locus selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the locus may be selected from SEQ ID NO.s:1-485512. In some embodiments, the kit can include one or more of methylation-dependent restriction enzymes, methylation-sensitive restriction enzymes, amplification (e.g., PCR) reagents, probes and/or primers. In some embodiments a reagent can determine the methylation states of at least about 1, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100 or more than 100 loci selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the at least about 1, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100 or more than 100 loci may be selected from SEQ ID NO.s:1-485512.

Some embodiments include kits for diagnosing, determining a prognosis, or determining or predicting a response to treatment of a subject with rheumatoid arthritis or osteoarthritis, comprising a reagent for determining the methylation state of at least one gene selected from the group consisting of the genes listed in TABLE 3. Some kits also include at least one polynucleotide primer comprising a sequence hybridizing to at least a portion of the at least one gene selected from the group consisting of the genes listed in TABLE 3. In some embodiments, the reagent comprises a restriction enzyme. In some embodiments a reagent can determine the methylation states of at least about 1, 5, 10, 20, 30, 40, 50, or more genes selected from the group consisting of the genes listed in TABLE 3.

Some embodiments include a nucleic acid array consisting essentially of nucleic acids useful for diagnosing rheumatoid arthritis or osteoarthritis, determining a prognosis of rheumatoid arthritis or osteoarthritis, or determining or predicting a response to treatment of a subject being evaluated for or suffering from rheumatoid arthritis or osteoarthritis. In some such embodiments, the nucleic acids comprise at least about 5 loci, at least about 10 loci, at least about 15 loci, at least about 20 loci, at least about 25 loci, at least about 50 loci, and at least about 100 loci. In some embodiments the loci are selected from the group consisting of the loci listed in TABLE 6, TABLE 7, or TABLE 8. In some embodiments, the loci may be selected from SEQ ID NO.s:1-485512.

Computer-Based Methods

The calculations for the methods described herein can involve computer-based calculations and tools. For example, a methylation value for a DNA region or portion thereof can be compared by a computer to a threshold value, as described herein. The tools are advantageously provided in the form of computer programs that are executable by a general purpose computer system (referred to herein as a “host computer”) of conventional design. The host computer may be configured with many different hardware components and can be made in many dimensions and styles (e.g., desktop PC, laptop, tablet PC, handheld computer, server, workstation, mainframe). Standard components, such as monitors, keyboards, disk drives, CD and/or DVD drives, and the like, may be included. Where the host computer is attached to a network, the connections may be provided via any suitable transport media (e.g., wired, optical, and/or wireless media) and any suitable communication protocol (e.g., TCP/IP); the host computer may include suitable networking hardware (e.g., modem, Ethernet card, WiFi card). The host computer may implement any of a variety of operating systems, including UNIX, Linux, Microsoft Windows, MacOS, or any other operating system.

Computer code for implementing aspects of the present invention may be written in a variety of languages, including PERL, C, C++, Java, JavaScript, VBScript, AWK, or any other scripting or programming language that can be executed on the host computer or that can be compiled to execute on the host computer. Code may also be written or distributed in low level languages such as assembler languages or machine languages.

The host computer system advantageously provides an interface via which the user controls operation of the tools. In the examples described herein, software tools are implemented as scripts (e.g., using PERL), execution of which can be initiated by a user from a standard command line interface of an operating system such as Linux or UNIX. Those skilled in the art will appreciate that commands can be adapted to the operating system as appropriate. In other embodiments, a graphical user interface may be provided, allowing the user to control operations using a pointing device. Thus, the present invention is not limited to any particular user interface.

Scripts or programs incorporating various features of the present invention may be encoded on various computer readable media for storage and/or transmission. Examples of suitable media include magnetic disk or tape, optical storage media such as compact disk (CD) or DVD (digital versatile disk), flash memory, and carrier signals adapted for transmission via wired, optical, and/or wireless networks conforming to a variety of protocols, including the Internet.

Some embodiments include methods for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising accessing first data representing nucleic acid loci which are differentially methylated in individuals with rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis wherein said data is stored on a non-transitory computer readable medium. Some embodiments also include instructing a computer to compare said first data to second data representing the methylation status of said nucleic acid loci in a sample taken from said subject, wherein said data representing the methylation status of said nucleic acid loci in a sample taken from said subject is stored on a non-transitory computer readable medium. Some embodiments also include diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in said subject if said first data representing the methylation status of said nucleic acid loci in a sample taken from said subject are significantly similar to said second data representing nucleic acid loci which are differentially methylated in individuals with rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.

While the present invention has been described in some detail for purposes of clarity and understanding, one skilled in the art will appreciate that various changes in form and detail can be made without departing from the true scope of the invention.

EXAMPLES Example 1 Methylation of Loci in RA and OA Patients Methods: Fibroblast-Like Synoviocytes

FLS were isolated from synovial tissues obtained from RA and OA patients at the time of joint replacement as described previously. The diagnosis of RA conformed to the American College of Rheumatology 1987 revised criteria. The protocol was approved by the UCSD Human Subjects Research Protection Program. Synovial tissues were minced and incubated with 0.5 mg/ml collagenase VIII (Sigma) in serum-free RPMI (Mediatech, VA) for 1.5 h at 37° C., filtered through a 0.22 μm cell strainer, extensively washed, and cultured in DMEM supplemented with 10% FCS (endotoxin content<0.006 ng/ml; Gemini Biosciences, CA), penicillin, streptomycin, gentamicin and L-glutamine in a humidified 5% CO₂ incubator. After overnight culture, nonadherent cells were removed, and adherent cells were trypsinized, split at a 1:3 ratio, and cultured. Synoviocytes were used from passage 4 through 9, when FLS were a homogeneous population with <1% CD11b, <1% phagocytic, and <1% FcR II positive cells.

Patient Phenotype

Synovial tissues were obtained at the time of clinically indicated total knee or hip joint replacement surgery except for one patient with RA who had wrist surgery. The mean ages of RA and OA patients were 53±9 and 68±16, respectively. Additional information on four patients (2 RA and 2 OA) was limited because the samples were de-identified. The erythrocyte sedimentation rates for the remaining RA and OA patients were 38±15 and 19±10, respectively. Of the 4 RA patients with clinical information, 3 were seropositive for serum rheumatoid factor or anti-CCP antibody and all were treated with low dose prednisone, 2 with methotrexate, 2 with a TNF blocker, and 1 with leflunomide. OA was mainly treated with acetaminophin and narcotics for pain.

Isolation of Genomic DNA and qPCR Analysis

RA and OA FLS were grown to 80% confluence and harvested. Genomic DNA of 10⁶ FLS was isolated using the MagMAX™ DNA Multi-Sample Kit (Applied Biosystems). DNA quality and quantity was assessed with a NanoDrop ND-2000 spectrometer (NanoDrop Technologies, Wilmington, Del., USA). mRNA from cultured FLS was isolated using RNA-STAT (Tel-Stat, TX) and cDNA was prepared, according to manufacturer's instructions using GeneAmp 2400 (Applied Biosystems). Quantitative real-time PCR was performed using Assays On Demand (Applied Biosystems) to determine relative mRNA levels using the GeneAmp 5700 Sequence Detection System (Applied Biosystems) as described previously. Standard curves for human MMP1 and GAPDH were generated. Sample Ct values were used to calculate the number of cell equivalents in the test samples. The data were then normalized to GAPDH expression to obtain relative cell equivalents.

Infinium HumanMethylation450 Chip Analysis

Genomic DNA was isolated from female RA and OA FLS as described. The Infinium HumanMethylation450 chip was processed as described by the manufacturer (Illumina, San Diego, Calif.). This chip covers 96% of RefSeq genes and provides comprehensive gene region coverage, targeting multiple sites with promoter, 5□ UTR, 1st exon, gene body and 3□ UTR. Initial analysis was performed with the Genome Studio methylation module, and then further analysed as described herein. The methylation level of a loci is measured as:

β=M/(U+M+100)

M is the fluorescence level of the methylation probe and U is the methylation level of the unmethylated probe. A constant value of 100 is added to prevent division by a small number (or 0) when background subtraction was used. The β values varied from 0 (completely unmethylated) to 1 (completely methylated). To measure the difference in methylation at a loci between OA and RA the average β levels were compared.

Method for Determining Enrichment of Multiple Methylated Loci

To avoid taking a single P-value cut-off when identifying genes that are enriched with differentially methylated (differentially methylated) loci, a variable cut-off scheme was used. Loci were ranked by their differentially methylated P-values. Then a P-value cut-off was taken. Those loci with P-value beneath the cut-off were taken to be differentially methylated and the rest were taken as not being differentially methylated. While doing this all P-value cut-offs beneath 0.05 were tried. Then for each gene, with loci beneath the P-value cut-off, the level which its loci were enriched beneath the cut-off was calculated as its enrichment factor (EF).

EF=(number of loci from gene A beneath cut-off/total loci from gene A)/(total number of loci beneath cut-off/total number of loci)

If EF is greater than 1 then it means the genes loci are enriched with differentially methylated loci. For those genes with an EF greater than 1, a P-value for the level of enrichment was calculated using the hypergeometric distribution. The resulting P-values were corrected with the Benjamini-Hochberg correction. Genes with enrichment P-values beneath <0.05 were recorded. If a gene was found to be enriched at multiple loci differentially methylated levels then only the level with the lower enrichment P-value was reported.

Pathway and Gene Ontology Analyses

Pathway enrichment was carried out using the KEGG human pathways and modules (www.genome.jp/kegg/download). The enrichment analysis of 1859 loci was performed by mapping pathway to loci via the loci gene annotations, the EF of loci being enriched in KEGG pathway as calculated. If EF was greater than 1 then P-value for the level of enrichment was calculated using the hypergeometric distribution. The resulting P-values were corrected with the Benjamini-Hochberg correction. As the KEGG pathways represent groups of related bimolecular pathways a P-value cut-off of <0.1 was used as it would allow enrichment within individual bimolecular pathways to be identified. A P-value cut-off of <0.1 has been used previously during KEGG pathway analysis (Xu et al. 2010-Revealing parasite influence in metabolic pathways in Apicomplexa infected patients, BMC Bioinformatics 2010, 11(Suppl 11):S13; Shen et al. 2006—Sepsis Plasma Protein Profiling with Immunodepletion, Three-Dimensional Liquid Chromatography Tandem Mass Spectrometry, and Spectrum Counting, J. Proteome Res., 2006, 5 (11), pp 3154-3160, each incorporated by reference in their entireties). Gene ontology (GO) analysis was carried using human GO term associations (www.geneontology.org). GO term enrichment analysis was carried out using model-based gene set analysis which uses probabilistic inference to identify the active GO terms (Bauer, et al. 2010 GOing Bayesian: model-based gene set analysis of genome-scale data. Nucleic Acids Res. 2010; 38:3523-32, incorporated by reference in its entirety). This approach naturally deals with overlapping GO categories and avoids the need for multiple testing correction. Marginal probability values>0.50 were considered significantly enriched.

Initial Probe and Data Filtering

The DNA methylome in RA and control (OA) FLS was evaluated. The Infinium HumanMethylation450 chip (Illumina, Inc.) was used to determine the methylation status of 485,512 loci from FLS isolated from 11 female patients at the time of total joint replacement surgery (6 RA; 5 OA). Loci were removed from subsequent analysis if any of the probes for a locus could not be disguised from background with a P-value<0.01 or if enough beads present upon the chip for accurate measurement of their methylation level. After filtering, 476,331 loci were available for further analysis.

Global Methylation Status

To assess global methylation status of RA and OA FLS, the methylation scores over all filtered loci within a sample were summed. The difference between the two samples was assessed using Student's t-test. Initial analysis included all loci and was then repeated for only loci located in promoters. There were no significant differences between RA and OA (P-values 0.528 and 0.627, respectively). Therefore, globally hypo- or hypermethylation is not associated with RA when compared to OA. These results were confirmed using an antibody-based method to determine methylcytosine levels (Active Motif, Inc., Carlsbad, Calif.) where global methylation were similar for RA and OA (RA=0.85±0.32; OA=1.00±0.24; n=10 RA and 9 OA lines; P>0.05).

Analysis of Differentially Methylated Individual Loci

Although global methylation are not different for RA and OA, there were differentially methylated (differentially methylated) loci that cluster to the two diseases. To identify the autosomal loci that are differentially methylated between OA and RA two filters were used: (i) an average difference in methylation level was greater than 0.1; and (ii) a P-value<0.05 that calculated using the Student's t-test and corrected for multiple testing with the Benjamini-Hochberg adjustment. 1,859 loci in 1206 different genes were identified as significantly differentially methylated in RA FLS. TABLE 1 shows example numbers of hypermethylated and hypomethylated sites.

TABLE 1 No. of loci No. of loci hypomethylated hypermethylated in RA in RA differentially methylated loci* 732 1127 differentially methylated genes** 63 144 differentially methylated KEGG 10 6 pathways differentially methylated GO 138 242 terms *differentially methylated = Differentially methylated; Difference between OA and RA > 0.1, with P < 0 after Benjamini-Hochberg adjustment. **6 additional genes had both hypo- and hypermethylated loci (ADAMTS2, C7orf50, DIP2C, FRMD SH3PXD2A)

Examples of genes identified with statistically significant differences between RA and OA at an individual locus using the ILLUMINA dataset are shown in TABLE 2. A mean value of OA methylation minus RA methylation; A P-value cut-off of <0.05 was used for determining significance. Where the RA minus OA value was positive the locus in RA was hypermethylated; where the RA minus OA value was negative, the locus in RA was hypomethylated.

TABLE 2 RA minus OA Gene Description Hyper- −0.34417 PHLPP1 PH domain and leucine rich repeat protein phosphatase 1 methylated* −0.34108 RXRA retinoid X receptor, alpha −0.30861 CYFIP1 cytoplasmic FMR1 interacting protein 1 −0.30363 ADAMTS2 ADAM metallopeptidase with thrombospondin type 1 motif, 2 −0.2964 CD55 CD55 molecule, decay accelerating factor for complement −0.27459 CABLES1 Cdk5 and Abl enzyme substrate 1 −0.26569 HAS1 hyaluronan synthase 1 −0.25362 ITGB8 integrin, beta 8 −0.25333 HBEGF heparin-binding EGF-like growth factor −0.23299 PTPN14 protein tyrosine phosphatase, non-receptor type 14 −0.23228 COL4A2 collagen, type IV, alpha 2 −0.23122 COL4A1 collagen, type IV, alpha 1 −0.21314 TGFBR2 transforming growth factor, beta receptor II (70/80 kDa) −0.20915 EGF epidermal growth factor −0.20692 ITGBL1 integrin, beta-like 1 (with EGF-like repeat domains) −0.20006 TIMP2 TIMP metallopeptidase inhibitor 2 −0.19768 MAP3K1 mitogen-activated protein kinase kinase kinase 1 −0.19005 FOXO1 forkhead box O1 Hypo- 0.365 CHI3L1 Chitinase 3-like 1 (cartilage glycoprotein-39) methylated 0.337 WISP3; WNT1 inducible signaling pathway protein 3 WISP3 0.333 STK24 serine/threonine kinase 24 0.329 MMP20 matrix metallopeptidase 20 0.322 EGFLAM EGF-like, fibronectin type III and laminin G domain 0.318 PTGIS prostaglandin I2 (prostacyclin) synthase 0.301 DCBLD1 discoidin, CUB and LCCL domain containing 1 0.299 MAP3K5 mitogen-activated protein kinase kinase kinase 5 (ASK1) 0.297 MGMT O-6-methylguaninE−DNA methyltransferase 0.282 CDK14 Cyclin-dependent kinase 14 0.272 STAT3 signal transducer and activator of transcription 3 0.270 ADAM32 ADAM metallopeptidase domain 32 0.264 RASGRF2 Ras protein-specific guanine nucleotidE−releasing factor 2 0.253 CASP1 caspase 1, apoptosis-related cysteine peptidase 0.225 P2RX6 purinergic receptor P2X, ligand-gated ion channel, 6 0.195 TRAF2 TNF receptor-associated factor 2 0.185 MEFV Mediterranean fever

CpG methylation was significantly different in a number of genes implicated in RA. Several genes implicated in inflamation and immune responses are differentially methylated in RA.

A list of 1,859 loci is shown in TABLE 6 and TABLE 7. TABLE 6 and TABLE 7 list loci which are differentially methylated in RA compared to OA; a positive OA-RA value represents a loci which is hypomethylated in RA FLS (TABLE 6), a negative OA-RA value represents a loci which is hypermethylated in RA FLS (TABLE 7).

Permutation analysis was carried out to assess the significance of loci identified as differentially methylated. The 11 samples were randomly assigned to OA and RA while maintaining the same number of OA and RA labels, i.e., 5 OA and 6 RA. The permutation analysis was repeated 1,000 times. The average number of significant loci during the permutation analysis was 4.9, compared to 1,859 for the correct disease identification. The permutation analysis strongly supports these loci as truly differentially methylated and not as a result of random chance.

To assess the ability of the 1,859 loci to distinguish OA from RA, the methylation patterns of the loci across the 11 samples were hierarchically clustered (FIG. 2). The clustering of the samples distinguishes OA from RA, which clearly segregate according to disease type. The clustering of the loci also shows that groups of loci have similar patterns of differentially methylated across the samples.

Analysis of Genes with Multiple Differentially Methylated Loci

To examine genes that were significantly differentially methylated between OA and RA, genes that were enriched with multiple differentially methylated loci were identified (see Methods). This analysis was carried using all 1,859 differentially methylated loci identified in differentially methylated loci section. The data demonstrated that many genes have multiple CpGs that are hyper- or hypo-methylated. For example, COL1A1 has 41 loci, and 4 are hypomethylated in RA (P<10⁻⁶) giving a “relative enrichment” of 79-fold compared to OA. Relative enrichment for MEFV (pyrin) hypomethylation is nearly 200-fold. Of interest, 4 of 16 loci in the TNF promoter are hypermethylated in RA (relative enrichment-451; P<10⁻⁹), suggesting that TNF regulation might be under the control of DNMTs in some patients. 207 genes were either enriched for multiple hyper- or hypomethylated loci (TABLE 1). Representative examples of hypomethylated- (hypo-) and hypermethylated- (hyper-) differentially methylated genes are shown in TABLE 3.

TABLE 3 No. of differentially Total methylated loci Enrich- Status loci beneath on P-value for ment in RA Gene cut-off array enrichment factor hypo LOC146880 9 32 9.96E−18 245.34 hypo SH3D20 6 15 5.58E−14 487.22 hypo TACC2 7 70 4.60E−11 87.23 hypo KCNJ9 4 15 1.95E−08 251.27 hypo FUT4 4 20 4.90E−08 200.26 hypo ARHGAP27 4 25 2.45E−07 130.45 hypo OLFML3 3 9 2.97E−07 439.51 hypo ACTN1 4 42 3.73E−07 116 hypo TRIM15 4 82 3.79E−07 115.32 hypo PDZRN3 4 50 9.44E−07 88.29 hypo COL1A1 4 41 1.26E−06 79.55 hypo CD93 3 15 2.44E−06 200.26 hypo ITGA4 3 18 4.52E−06 157.79 hypo NFE2L3 3 19 7.74E−06 128.74 hypo HRNBP3 5 189 8.88E−06 25.05 hypo POMC 3 26 1.00E−05 115.53 hypo SKAP1 3 27 1.09E−05 111.26 hypo T 3 31 1.21E−05 106.8 hypo RHOJ 2 9 2.16E−05 525.33 hypo COL22A1 3 36 2.26E−05 83.44 hypo BOC 3 35 2.32E−05 81.15 hypo SCUBE1 2 23 6.91E−05 273.55 hypo ROBO4 2 15 7.76E−05 252.46 hypo HUNK 2 16 8.36E−05 236.68 hypo AUTS2 3 114 8.36E−05 49.83 hypo FPR2 2 11 9.00E−05 221.46 hypo CASZ1 4 174 9.41E−05 21.76 hypo MEFV 2 11 9.64E−05 200.66 hypo MXRA8 2 18 9.64E−05 210.38 hypo ARMC3 2 12 9.64E−05 203.01 hypo STX1B 2 15 9.64E−05 199.51 hypo USP54 2 9 9.64E−05 193.85 hypo PLCH2 3 64 0.000112844 40.89 hypo FXYD7 2 17 0.000112844 176.04 hypo INSM1 2 13 0.000113996 169.79 hypo MYEF2 2 13 0.000113996 169.79 hypo P2RY6 2 21 0.000156705 142.51 hypo CA4 2 15 0.000227225 116.31 hypo AXIN2 2 37 0.000287729 102.35 hypo SPSB1 2 46 0.000287729 102.78 hypo KANK4 2 21 0.000316358 95.36 hypo APCDD1 2 20 0.000419791 81.53 hypo B3GNTL1 3 158 0.000474472 23.13 hypo ANGPT1 2 24 0.000585029 67.95 hypo PRRX1 2 27 0.000625725 64.62 hypo COL6A1 2 33 0.000696287 60.68 hypo LRIG1 2 46 0.000726192 59.28 hypo GLIS1 2 50 0.000828923 54.54 hypo ST14 2 43 0.000921733 51.33 hypo SYT7 2 54 0.001010062 48.83 hypo PHC2 2 34 0.001014634 47.96 hypo PLXNC1 2 34 0.001014634 47.96 hypo PKNOX2 2 63 0.001243393 43.29 hypo ODZ4 2 148 0.001280632 42.51 hypo MYO7A 2 45 0.001280907 42.08 hypo EBF2 2 47 0.001382296 40.29 hypo NXN 3 193 0.002031781 12.67 hypo PRKAR1B 3 224 0.002535422 11.68 hypo SYNJ2 2 68 0.002651843 27.84 hypo MAML2 2 70 0.002780925 27.05 hypo GAS7 2 72 0.003896102 22.65 hypo MYT1L 2 170 0.006150038 17.6 hypo SMOC2 2 164 0.01010976 13.46 hyper LOC90834 8 11 7.31E−18 375.88 hyper BRD1 8 42 1.65E−12 98.45 hyper C6orf25 5 42 1.90E−09 208.6 hyper PCSK6 7 65 2.09E−09 55.66 hyper LOC100292680 4 13 2.07E−08 291.99 hyper PPM1L 5 37 6.18E−08 88.51 hyper FERMT3 4 21 1.05E−07 180.76 hyper TES 4 21 3.42E−07 132.58 hyper PHYHD1 3 9 1.09E−06 316.32 hyper IGSF6 3 6 1.21E−06 275.53 hyper UACA 3 22 2.44E−06 238.95 hyper TNF 4 27 2.66E−06 71.05 hyper PRMT7 3 24 2.98E−06 219.03 hyper SEC14L3 3 9 3.07E−06 197 hyper HSD3B7 3 17 3.07E−06 208.59 hyper APP 2 19 3.30E−06 2002.59 hyper MYPN 3 11 3.44E−06 189.82 hyper HBEGF 3 10 3.74E−06 177.3 hyper SLC22A1 3 13 3.74E−06 182.93 hyper LOC100271831 3 9 5.20E−06 151.33 hyper GPR1 3 14 6.06E−06 149.15 hyper NINJ2 4 39 6.06E−06 53.01 hyper GDPD3 3 10 6.90E−06 136.2 hyper C21orf34 3 16 8.70E−06 130.5 hyper KHDRBS3 3 17 1.24E−05 115.58 hyper TRERF1 4 50 1.49E−05 41.35 hyper COL4A2 5 139 1.53E−05 22.99 hyper MIRLET7C 2 4 2.05E−05 591 hyper SPATA18 3 27 3.95E−05 77.34 hyper SEMA6D 3 22 5.67E−05 65.4 hyper METTL9 3 25 5.67E−05 66.13 hyper TIMP2 4 64 5.67E−05 28.37 hyper KIAA1949 4 100 6.11E−05 27.84 hyper NRM 2 43 8.35E−05 299.71 hyper NSMCE2 3 32 0.000105867 51.66 hyper SLC9A1 3 27 0.000109957 50.44 hyper C17orf99 2 10 0.000113832 236.4 hyper MIR1301 2 6 0.000143314 197 hyper PLXNA2 3 45 0.00015859 43.66 hyper GALNT12 2 9 0.00018091 176.15 hyper STX2 3 38 0.000181317 40.8 hyper CPT1A 3 59 0.000185452 40.31 hyper EHD4 3 36 0.000185452 39.97 hyper MYH15 2 14 0.000191884 168.86 hyper FGL2 2 6 0.000226795 144.6 hyper RPH3AL 4 154 0.000226795 18.08 hyper SCARA5 3 39 0.000253629 34.92 hyper BTC 2 14 0.000270028 135.57 hyper CETN1 2 11 0.00029116 126.55 hyper NPL 2 8 0.000332725 113.5 hyper LARP4 2 20 0.000332725 118.2 hyper NADK 3 47 0.000334772 30.61 hyper ITPK1 3 65 0.000345734 30.23 hyper ZEB2 3 59 0.000346791 30.05 hyper CCDC25 2 12 0.000360628 106.54 hyper TMOD4 2 9 0.000360628 106.58 hyper EGF 2 13 0.000360628 107.08 hyper SLC1A2 2 32 0.000360628 109.52 hyper ADCK5 2 22 0.000364838 107.45 hyper RNF165 2 16 0.000413716 99.09 hyper CSNK1G2 3 53 0.000425925 27.15 hyper ERRFI1 2 20 0.000448119 94.9 hyper ESCO2 2 14 0.000464905 91.32 hyper CHST11 3 55 0.000464905 26.16 hyper MUC6 3 56 0.00047946 25.69 hyper ITGB8 2 13 0.00050411 84.78 hyper ST5 3 71 0.00050411 24.97 hyper FANCA 2 28 0.000525004 84.43 hyper MYF6 2 11 0.00055928 78.87 hyper SETD1A 2 30 0.000588655 78.8 hyper RUFY3 2 17 0.000595625 77.05 hyper MYOM1 2 12 0.000597351 75.67 hyper ARL4D 2 15 0.000638325 73.47 hyper NXPH2 2 21 0.000774146 66.29 hyper MGAT3 2 18 0.000776579 65.67 hyper AKT3 2 30 0.000841298 63.26 hyper RELL1 2 23 0.000896152 60.52 hyper CARS 2 23 0.000896152 60.52 hyper TRAPPC9 4 215 0.000916221 11 hyper LZTS1 2 22 0.000916221 59.54 hyper PPP2R5C 2 59 0.000924708 59.4 hyper DLX3 2 16 0.000963235 56.75 hyper AMBRA1 2 28 0.000986075 56.62 hyper SDCBP2 2 24 0.001039634 54.58 hyper LMBRD1 2 17 0.00105958 53.41 hyper ARHGAP1 2 18 0.00106039 53.29 hyper TBCD 5 352 0.001086318 7.34 hyper ACSL1 2 30 0.001086318 52.85 hyper PLCB3 2 26 0.001238237 49.17 hyper MAP3K1 2 24 0.001394061 45.92 hyper LRRFIP1 2 76 0.001408026 46.11 hyper BAI2 2 36 0.001513586 44.04 hyper ZNRF1 2 26 0.001594799 42.39 hyper ITGBL1 2 23 0.001628294 41.71 hyper SPPL2B 2 38 0.001642638 41.72 hyper PIGV 2 23 0.001779686 39.48 hyper KLF12 2 40 0.001784969 39.63 hyper FOXO1 2 32 0.002026288 36.94 hyper C1QTNF1 2 39 0.002125118 35.69 hyper NCK2 2 53 0.002125118 35.81 hyper CYTH1 2 37 0.002143776 35.4 hyper APOLD1 2 34 0.002203548 34.76 hyper HTRA1 2 38 0.002233352 34.47 hyper CCDC146 2 28 0.002665635 30.98 hyper CRYL1 2 42 0.002665635 31.19 hyper COL4A1 2 71 0.003503044 26.73 hyper GPR133 3 165 0.003819221 10.75 hyper PHACTR2 2 40 0.004172106 23.98 hyper ANK3 2 38 0.004173533 23.89 hyper RPTOR 5 432 0.004520935 5.02 hyper CACNA2D3 2 76 0.005405541 20.86 hyper LHFPL2 2 44 0.005447591 20.64 hyper TG 2 47 0.00554287 20.41 hyper KANK2 2 45 0.005602318 20.18 hyper SRPK2 2 45 0.005602318 20.18 hyper PITPNM2 2 48 0.005684708 19.98 hyper ADAM12 2 52 0.005720838 19.88 hyper MICAL3 2 47 0.005961209 19.32 hyper FILIP1L 2 45 0.005961209 19.28 hyper GALNS 2 73 0.006100028 19.07 hyper ARHGAP26 2 61 0.006687473 18.07 hyper ARHGEF7 2 74 0.006937548 17.7 hyper WIPI2 2 64 0.007267014 17.22 hyper PTPN14 2 59 0.00801136 16.26 hyper CUX1 2 215 0.00801136 16.3 hyper SORBS2 2 81 0.00806007 16.17 hyper HPCAL1 2 60 0.008172002 15.99 hyper DNMT3A 2 77 0.00881667 15.35 hyper TNS3 2 79 0.009173569 14.96 hyper SLC6A3 2 69 0.009173569 14.98 hyper PTPRG 2 96 0.01090562 13.64 hyper MIR548G 2 65 0.01127773 13.35 hyper ASAP2 2 70 0.01183843 12.97 hyper C3orf26 2 67 0.01183843 12.95 hyper NAV1 2 68 0.01212126 12.76 hyper CREB5 2 82 0.01424866 11.7 hyper CTBP2 2 102 0.02110821 9.4 hyper TCERG1L 2 105 0.02218092 9.14 hyper SHANK2 3 262 0.02489354 4.97 hyper CMIP 2 113 0.02508337 8.49 hyper BAT2 2 161 0.02704674 8.14 hyper EIF2C2 2 117 0.02919953 7.76 hyper RPS6KA2 2 244 0.02919953 7.78 hyper PRKCZ 2 263 0.03328032 7.22

Correlation of Gene Expression and Methylation Status

Functional analysis of the differentially methylated was performed by evaluating expression of several representative genes with hypo- and normally methylated loci in RA FLS by qPCR. FIG. 3 shows the results for several hypomethylated genes. These genes included ITGA4, COL1A1, MYEF2, SYNJ2, CHI3L1, STK24, and MAP3K5. As a group, expression of genes with hypomethylated loci was significantly greater in RA than OA FLS (n=7 genes; P<0.01). On the other hand, expression of normally methylated genes was similar in RA and OA FLS (n=7 genes; P>0.10).

Higher expression in RA was demonstrated for most hypomethylated genes, and the differences were significant when the genes were evaluated as a group (P<0.01 for RA vs. OA). Some genes, such as STK24, were not significantly different in RA and could reflect more than methylation in vitro. Nevertheless, these data demonstrated that methylation is reflected in gene expression patterns in RA and could contribute to production of inflammatory mediators in RA.

Pathway and Gene Ontology Analyses

Biological pathways and gene ontologies that are enriched with differentially methylated loci were evaluated. Loci were mapped to pathways via their relationships to genes within pathways for KEGG pathways and for GO using all 1,859 differentially methylated loci identified (TABLE 1). Pathway analysis showed that interactions between cells and the matrix and cell recruitment were especially prominent in the differentially methylated group, including focal adhesion, mTOR signaling, cell adhesion molecules, leukocyte transendothelial interactions, and ECM-receptor interactions. FIG. 4 depicts the pathway ‘Focal adhesion’, which was enriched with loci that are significantly less methylated in RA. A list of differential GO terms and an analysis of hypomethylated and hypermethylated terms in RA with marginal probability>0.5 is shown in TABLE 4.

TABLE 4 Marginal ID probability Name RA GO: 0003713 0.99836 Transcription coactivator activity Hypomethylated GO: 0051117 0.98512 ATPase binding GO: 0031519 0.95603 PcG protein complex GO: 0045944 0.92189 Positive regulation of transcription from RNA polymerase II promoter GO: 0019897 0.81989 Extrinsic to plasma membrane GO: 0008134 0.81119 Transcription factor binding GO: 0015467 0.78847 G-protein activated inward rectifier potassium channel activity GO: 0017157 0.76244 Regulation of exocytosis GO: 0007369 0.74990 Gastrulation GO: 0035257 0.70985 Nuclear hormone receptor binding GO: 0004221 0.59229 Ubiquitin thiolesterase activity GO: 0004629 0.55446 Phospholipase C activity GO: 0009897 0.53595 External side of plasma membrane GO: 0015629 0.52284 Actin cytoskeleton GO: 0022610 0.51076 Biological adhesion RA GO: 0005794 0.77055 Golgi apparatus Hypermethylated GO: 0007166 0.76581 Cell surface receptor linked signaling pathway GO: 0005488 0.60305 Binding

Of interest, the number of GO terms associated with hypomethylated DNA in RA was greater than for hypermethylated DNA (15 vs. 3). Thus, hypomethylated terms clustered with hypomethylation in RA, especially related to membrane and transcription factor biology. This analysis can be used to identify novel therapeutic targets for RA. More examples of pathways useful to identify novel therapeutic targets for RA are shown in TABLE 5.

TABLE 5 DM loci Total Status Enrichment in loci in in RA Path group Path name factor path path P-value hypo Cell Communication Focal adhesion 2.615457643 20 6226 0.007005624 hypo Glycan Biosynthesis Glycosphingolipid 9.88097044 5 412 0.007005624 and Metabolism biosynthesis - lacto and neolacto series hypo Cardiovascular Arrhythmogenic right 3.862390722 10 2108 0.007378046 Diseases ventricular cardiomyopathy (ARVC) hypo Signaling Molecules ECM-receptor 3.303009997 12 2958 0.007378046 and Interaction interaction hypo Infectious Diseases Amoebiasis 3.278225332 11 2732 0.01087908 hypo Immune System Leukocyte 3.339589681 10 2438 0.01366817 transendothelial migration hypo Digestive System Protein digestion 3.090564183 9 2371 0.03435163 and absorption hypo Endocrine System Adipocytokine 3.505131458 7 1626 0.04363638 signaling pathway hypo Signaling Molecules Cell adhesion 2.542760663 10 3202 0.06198887 and Interaction molecules (CAMs) hypo Energy Metabolism Nitrogen metabolism 6.691988748 3 365 0.08527128 hyper Signal Transduction ErbB signaling 2.295320174 18 2272 0.0580967 pathway hyper Infectious Diseases African 4.05913013 8 571 0.0580967 trypanosomiasis hyper Lipid Metabolism Primary bile acid 5.625639088 4 206 0.0950006 biosynthesis hyper Immune System Fc epsilon RI 2.345183916 13 1606 0.0950006 signaling pathway hyper Signal Transduction mTOR signaling 2.295464506 14 1767 0.0950006 pathway hyper Endocrine System Adipocytokine 2.316337866 13 1626 0.0950006 signaling pathway

Network Analysis

Cytoscape was used to evaluate networks affected by differential methylation and to determine likely targets for subsequent analysis. In a preliminary study, interactions between hypomethylated genes and their neighbors were evaluated. A portion of the Cytoscape analysis is shown in FIG. 5. Significant nodes included key hypomethylated loci (e.g., STAT3, MAP3K5, CHI3L1, STK24) (circle size indicates degree of hypomethylation). FIG. 5 depicts how these loci interact with each other and with multiple additional pathways, and describes how the methylated genes might regulate inflammatory responses in RA. This map shows only a fraction of the interactions and provides an unbiased view of how methylation affects synoviocyte function.

Basal Expression of DNMTs

After discovering that RA FLS are differentially methylated, DNMT expression in resting cultured FLS was examined. Synoviocytes were isolated from RA and OA synovium at the time of total joint replacement. 4^(th) through 6^(th) passage cells were evaluated by qPCR. FIG. 6 depicts graphs of relative expression of DNMT1, DNMT3a, and DNMT3b in OA FLS and RA FLS. Unexpectedly, expression levels of DNMTs in RA and OA were found to be similar. In view of these findings, changes in DNMT expression in FLS was examined, and the role of cytokines, e.g., IL-1, in RA, that may contribute to a DNMT profile was examined.

Decreased DNMT1 Gene Expression after IL-1 Stimulation

FLS were stimulated with IL-1 for 24 hr and DNMT expression was determined by qPCR. Unexpectedly, DNMT1 and DNMT3a gene expression significantly decreased after exposure to modest concentrations of IL-1 (FIG. 7). After noting that IL-1 decreased DNMT mRNA, time course experiments were performed to assess the kinetics of the effect. Cells were stimulated with 1 ng/ml of IL-1 for various time periods and qPCR was performed. DNMT mRNA levels begin to decrease within 2 to 8 hrs after exposure to the cytokine (data not shown).

IL-1 Decreases DNMT Function in FLS

A functional assay was performed to determine if IL-1 suppresses DNA methylation activity of the DNMTs. FLS were stimulated with 1 ng/ml of IL-1 for 14 days and extracts were assayed using the DNMT Activity/Inhibition Assay (Active Motif Co., Carlsbad, Calif.), which is an ELISA-based method that measures methylation of a CpG-enriched DNA substrate. As shown in FIG. 8, a significant decline in total DNMT function (p<0.05) was observed.

Discussion

FLS form the synovial intimal lining and play an integral role in the pathogenesis of RA by producing key cytokines, small molecule mediators, and proteases. While osteoclasts are the primary effectors of bone erosions in arthritis, FLS are responsible for cartilage damage by virtue of their ability to adhere to and invade the cartilage extracellular matrix. This capacity requires homotypic aggregation mediated by the adhesion molecule cadherin-11, which directs intimal lining formation and supports an invasive phenotype. Understanding the molecular mechanisms that regulate FLS activation could provide insights into the pathogenesis of RA and lead to novel therapeutic strategies. In the present application, the epigenetic profile of RA was evaluated by exploring a newly discovered DNA methylation signature that could potentially affect adaptive and innate immune functions, through their effects on synoviocytes and immune cells in the blood and joint.

Rheumatoid FLS exhibit a unique aggressive phenotype that contributes to the cytokine milieu and joint destruction. Functional studies suggest that RA cells are imprinted in situ and maintain these features after many passages in tissue culture. For example, RA FLS, unlike OA or normal synoviocytes, adhere to and invade cartilage explants in SCID mice. RA FLS can grow under anchorage-independent conditions, are less susceptible to contact inhibition, resistant to apoptosis. RA synoviocytes can potentially “metastasize” and transfer the invasive phenotype from one joint to another.

Several mechanisms have been implicated in this persistently aggressive phenotype, including abnormal sentrin or PTEN expression, preferential shunting of stressed cells to DNA repair rather than programmed cell death., and somatic mutations of regulatory genes. Microsatellite instability has also been identified in RA synovium, in part due to decreased DNA repair. These genetic modifications potentially serve to amplify disease severity.

While the focus on gene sequences in FLS and in disease association studies has provided important insights, other mechanisms can change cell phenotype. Epigenetics, for instance, can profoundly influence cell activation and gene expression through a variety of mechanisms, including DNA methylation, histone modification, and microRNA production. DNA methylation could be especially relevant in RA, in light of role in neoplasia and embryonic growth. Normal ontogeny relies on a carefully orchestrated sequence of DNA methylation to repress regulatory genes by methylating cytosine in CpG loci, either in promoters or in genes themselves. Methylation abnormalities have been associated with many diseases, most notably cancer where renewed expression or inappropriate suppression of genes allows cells to escape normal homeostatic controls. Hypomethylation and hypermethylation are associated with many malignancies and can contribute to transformation.

DNA methyltransferases (DNMTs) are responsible for initiating and maintaining CpG methylation in the human genome by converting cytosine to methylcytosine. In mammalian cells, DNMT1, DNMT3a, and DNMT3b are the primary enzymes responsible for CpG methylation. DNMT3a and DNMT3b mainly regulate de novo methylation while DNMT1 maintains methylation, especially during cell division. DNMT expression and DNA methylation are not immutable but are influenced by the environment and modify gene expression throughout life and even in progeny. For instance, pregnant mice fed a diet rich in methyl donors give birth to pups with increased levels of DNA methylation and increased airway reactivity in murine asthma for at least two subsequent generations.

Global hypomethylation has been described in peripheral blood mononuclear cells of patients with RA, although the specific genes involved are not known. Modest global hypomethylation was also reported in cultured RA FLS when compared to OA cells. In contrast, our studies showed that global methylation levels are similar in OA and RA FLS using two different techniques (ELISA-based and chip based). Thus, RA FLS do not appear to be hypomethylated overall, but like neoplasia, display a pattern of hypermethylated and hypomethylated genes.

The ILLUMINA chip analysis identified distinct methylation profiles of OA and RA FLS involving 1859 loci located in 1206 genes. Cluster analysis showed that the two types of FLS could be easily distinguished based solely on the methylation patters. The results were confirmed using a variety of additional analyses that reduced the possibility of random chance as an explanation. Additional analysis identified 207 genes with multiple hyper- or hypomethylated loci. Many of these genes play a key role in inflammation, matrix regulation, leukocyte recruitment and immune responses. Gene expression levels correlated with methylation status, with high expression in hypomethylated genes in RA FLS and normal expression in genes that were not differentially methylated. Given the number of influences that can potentially alter gene expression in vitro, the general concordance between methylation and mRNA levels was striking.

The data described herein provide evidence that epigenetic changes are present in RA synoviocytes and that they persist in culture. Imprinting could potentially occur before clinical disease and contribute to susceptibility. Alternatively, and perhaps more likely, the changes can be induced after initiation of synovitis. In the latter situation, the inflammatory milieu could potentially imprint synoviocytes and affect their function for many passages. Thus, local inflammation could potentially alter expression of enzymes responsible for initiating and maintaining DNA methylation. This process imprints synoviocytes, peripheral blood cells that are present in synovium for a short period of time, and immune cells, alters their behaviour, and ultimately changes the natural history of disease.

The ability to distinguish RA and control cells based solely on the DNA methylome could provide major insights into how the epigenetic profile of various tissues contribute to the pathogenesis of RA. In addition to identifying novel targets among the differentially methylated genes, it could also lead to interesting diagnostic or personalized medicine applications after sufficient data are available to correlate the methylome to phenotype.

Example 2 Methylation of Loci in Peripheral Blood Cells

Isolation of Genomic DNA from Peripheral Blood Cells

Approximately 6-8 ml of blood was drawn into a DB CPT tube (BD cat#362760) and inverted 10 times. Four tubes per patient were drawn. The tubes were stored at room temperature until processed. Processing was performed in less than four hours after being drawn. The tubes were spun 30 minutes at 3000 rpm. The mononuclear cell layer was carefully removed and washed in at least 10 volumes of cold PBS with 0.1% BSA (Buffer 1: PBS Invitrogen cat#14190, BSA Gemini cat#700-100P). Mononuclear cells were then spun at 1600 rpm for 10 minutes. Cells were then resuspended in 3 ml of cold PBS supplemented with 0.1% BSA and 2 mM EDTA (Buffer 2: Buffer 1 plus EDTA Invitrogen cat#15575020). Cells were then counted and divided into 2 ml eppendorf tubes as follows: 0.5 ml for T-cell isolation, 1.5 ml for B-cell isolation, 0.75 ml for monocyte isolation, and 0.25 ml for whole PBMCs. These were spun again at 1600 rpm for 10 minutes and supernatants were discarded. The whole PBMC fraction was frozen while the others continued the specific cell type separation.

Separation of PBMCs into Specific Cell Types

Cells in the PBMC preparation above were separated into B cell preparations, T cell preparations and monocyte preparations as follows. Dynabeads magnetic beads (CD19 pan B Invitrogen cat#111-43D, CD2 pan T Invitrogen cat#111-59D, CD14 monocyte Invitrogen cat#111-49D) were used for the specific cell-type isolation. The magnetic bead mixtures were added to 1 ml of cold Buffer 2 according to the number of cells (50 μl T-cell bead isolation mixture per 10⁷ cells, 25 μl B-cell bead isolation mixture per 2.5×10⁷ cells, and 25 μl monocyte isolation bead mixture per 10⁷ cells), mixed well and applied to the magnet for 3 minutes to wash the beads. Supernatants were discarded. Mononuclear cell pellets were then gently resuspended in 1.5 ml of cold buffer 2 and added to their appropriate bead isolation mixture. The bead/cell mixture was incubated at 4° C. while turning end-over-end for 20 minutes. The bead/cell mixture was then applied to the magnet for 3 minutes and supernatants were discarded. The bead/cell mixture was then washed 3 times by removing from the magnet, adding 1 ml cold Buffer 2, gently mixing, reapplying to the magnet, and discarding the supernatant. The cell/bead mixture was then frozen until DNA Isolation was performed. The DNA isolation was performed with DNeasy Blood and tissue Kit (Qiagen cat#69504). The protocol for cultured cells was followed and included the recommendation of RNase A (Qiagen cat#19101) treatment. DNA eluents were then concentrated using Amicon ultra 30K filers (Millipore cat# UFC503096). Concentrated DNA was then quantified using Quant-it Picogreen reagent (Invitrogen cat# P7589). Concentrations were then standardized to 100 ng/μl.

PBMC preparations may also be separated into other cell types, such as white blood cells, neutrophils, eosinophils, basophils, lymphocytes, plasma cells, natural killer cells, and dendritic cells using procedures such as those described above or other methods familiar to those skilled in the art. Macrophages may be separated from other cell types using methods well known in the art. In some embodiments, particular cell types can be enriched and/or isolated using a variety of methods, such methods are well known in the art and include immunological methods, fluorescent activated cell sorting (FACS) methods, and affinity chromatography methods. For example, cells such as eosinophils can be enriched/isolated using antibodies specific to specific receptors on the cell surface such as L-selectin, and VLA-4 (Sriramarao P., et al., (1994) J. Immunol. 153:4238-46, incorporated by reference in its entirety) Neutrophils may be isolated using density gradients or using antibodies specific to other cell surface receptors (Firestein G. S., et al., (1995) J. Immunol. 154:326-34, incorporated by reference in its entirety).

Analysis of Methylation States of Loci in PBMCs or Specific Cell Types Separated from PBMC Preparations in Individuals with RA or OA

Samples of genomic DNA are obtained from peripheral blood mononuclear cells or specific cell types separated from PBMC preparations as described above. The samples are obtained from individuals with RA, individuals with OA, individuals with a known prognosis for rheumatoid arthritis or osteoarthritis, individuals with a known reponse to treatment for rheumatoid arthritis or osteoarthritis and control subjects without rheumatoid arthritis, without osteoarthritis, without the known prognosis for rheumatoid arthritis or osteoarthritis, or without the known response to treatment for rheumatoid arthritis or osteoarthritis using methods described herein. The methylation states of loci for each set of genomic DNA is determined as described herein for genomic DNA from FLS cells.

Hypomethylated and hypermethylated loci in individuals with RA, individuals with OA, individuals with a known prognosis for rheumatoid arthritis or osteoarthritis, individuals with a known response to treatment for rheumatoid arthritis or osteoarthritis are identified by comparing the methylation states of the loci to the methylation states of the loci in control subjects without rheumatoid arthritis, without osteoarthritis, without the known prognosis for rheumatoid arthritis or osteoarthritis, or without the known response to treatment for rheumatoid arthritis or osteoarthritis respectively using the methods described herein for FLS cells.

In some embodiments, hypomethylated and hypermethylated loci in RA genomic DNA relative to the methylation state of loci in OA genomic DNA are identified. In other embodiments hypomethylated and hypermethylated loci in RA genomic DNA relative to the methylation state of loci in genomic DNA from control subjects without RA are identified. In some embodiments, hypomethylated and hypermethylated loci in OA genomic DNA relative to the methylation state of loci in genomic DNA are identified from control subjects without OA are identified.

Genes with multiple differentially methylated loci are analyzed as described herein for genomic DNA from FLs cells, Gene expression and methylation status are analyzed as described herein for genomic DNA from FLs cells, Pathway analyses and gene ontology analyses are performed as described herein for genomic DNA from FLs cells. Network and DNMT analyses as described herein for genomic DNA from FLs cells.

Example 3 Evaluation of a Subject for RA,OA, Individuals with RA, a Particular Prognosis for Rheumatoid Arthritis or Osteoarthritis, or a Particular Response to Treatment for Rheumatoid Arthritis or Osteoarthritis

Genomic DNA is obtained from a subject and the methylation states of one or more loci having differential methylation in individuals with individuals with RA, individuals with OA, individuals with a particular prognosis for rheumatoid arthritis or osteoarthritis, or individuals with a particular response to treatment for rheumatoid arthritis or osteoarthritis is determined.

In some embodiments, the methylation state of the one or more differentially methylated loci in the genomic DNA from the subject is compared with the methylation state of the one or more differentially methylated loci in normal tissue, tissue from a subject with a known prognosis, or tissue from a subject with a known response to treatment. In other embodiments, the methylation state of the one or more differentially methylated loci in the genomic DNA from the subject is compared with a methylation state of the one or more differentially methylated loci known to be indicative of RA or a lack thereof, OA or a lack thereof, a particular prognosis for rheumatoid arthritis or osteoarthritis or a lack thereof, or a particular response to treatment for rheumatoid arthritis or osteoarthritis or a lack thereof.

The genomic DNA may be obtained from any desired cell type, including the cell types listed herein. For example, the genomic DNA may be obtained from FLS cells, a peripheral blood sample or a specific cell type separated from a PBMC sample obtained from a subject. If the methylation state of the one or more differentially methylated loci is a methylation state known to be indicative of RA, a particular prognosis for rheumatoid arthritis or osteoarthritis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis the subject is determined to have RA, the particular prognosis for rheumatoid arthritis or osteoarthritis, or the particular response to treatment for rheumatoid arthritis or osteoarthritis. A treatment regimen consistent with this determination may then be administered.

Example 4 Evaluation of a Methylation State of Loci in Control Subjects Compared to Methylation State of Loci in RA FLS and OA FLS

Genomic DNA is obtained from a subject without RA and a subject without OA and the methylation states of one or more loci having differential methylation in RA FLS and OA FLS cells, respectively, is determined.

In some embodiments, the methylation state of the one or more differentially methylated loci in RA FLS and OA FLS cells is compared to a methylation state of the one or more differentially methylated loci in the genomic DNA from a subject without RA and in the genomic DNA from a subject without OA, respectively. In some embodiments, the methylation state of loci indicative of the absence of RA or OA in a subject are determined.

The genomic DNA may be obtained from any desired cell type, including the cell types listed herein. For example, the genomic DNA may be obtained from FLS cells, a peripheral blood sample or a specific cell type separated from a PBMC sample obtained from a subject. If the methylation state of the one or more differentially methylated loci is a methylation state known to be indicative of RA, a particular prognosis for rheumatoid arthritis or osteoarthritis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis the subject is determined to have RA, the particular prognosis for rheumatoid arthritis or osteoarthritis, or the particular response to treatment for rheumatoid arthritis or osteoarthritis. A treatment regimen consistent with this determination may then be administered.

Example 5 Evaluation of Methylation State of Loci in Peripheral Blood Mononuclear Cells (PBMCs)

The methylation states of loci in PBMCs were determined with methods substantially similar to those described herein using the ILLUMINA HumanMethylation 450 BeadChip. Differentially methylated loci (DML) were identified with average methylation differences between OA and RA of >0.10. RA/OA differential methylation was conducted using a t-test. P-values were converted to q-values to account for multiple hypothesis testing, and DML with q-values<0.25 were considered to be potential PBMC biomarkers. TABLE 8 lists about 2544 RA/OA PBMC DML with associated data including the OA-RA average methylation difference, CG identifier associated with the Illumina 450K beadchip (Locus), associated genes, and the genomic location of the potentially methylated C of the CpG (+ strand) determined using the UCSC hg19 reference genome. The CpG* column of Table 8 lists values for “chromosome:chromosome co-ordinate.”

TABLE 6 OA − SEQ RA Locus Associated gene ID No. 0.39071 cg20114732 T 361932 0.37096 cg03044684 HUNK 62005 0.36569 cg20824939 372791 0.36469 cg19081101 CHI3L1 345293 0.36368 cg13225830 243918 0.36153 cg27244773 ARHGAP27; ARHGAP27; 475250 ARHGAP27 0.34388 cg02792136 DIP2C 56847 0.33702 cg12557114 WISP3; WISP3 233566 0.33333 cg06043820 ZNF592 119061 0.33296 cg07804470 STK24 151872 0.33037 cg12578486 UBAC2; UBAC2; UBAC2 233879 0.32914 cg18886274 342488 0.32889 cg12651286 MMP20 235219 0.32591 cg10035831 RPTOR; RPTOR 191245 0.32183 cg12476044 EGFLAM; EGFLAM; EGFLAM; 232241 EGFLAM; EGFLAM 0.32154 cg16214653 298250 0.32018 cg06550177 127813 0.31828 cg06357305 PTGIS 124318 0.31549 cg27250435 475334 0.31524 cg24203758 SH3D20 425444 0.31391 cg18675043 SH3PXD2A 338965 0.30767 cg11173579 HUNK 210693 0.30665 cg21514164 383094 0.30602 cg21670717 385687 0.30248 cg09182085 176526 0.30113 cg09230154 MACF1; MACF1 177251 0.30097 cg27642470 DCBLD1 482028 0.2993 cg23413809 SIX2 412582 0.29885 cg07474842 MAP3K5 1415804 0.29665 cg23004031 MGMT 405673 0.29622 cg02727484 KCNMA1; KCNMA1; KCNMA1; 55565 KCNMA1 0.29494 cg07227049 VRK2; VRK2; VRK2; VRK2; 141396 VRK2; VRK2 0.28978 cg06223539 SHANK2 122219 0.28958 cg19674091 IDH2 354510 0.28897 cg06966660 TACC2; TACC2; TACC2; TACC2 136119 0.28527 cg22778178 401834 0.28511 cg12427162 SFT2D2 231416 0.28455 cg16854917 NCRNA00085 309652 0.28177 cg03834767 CDK14 77306 0.28129 cg17820022 PLCH2 324801 0.27987 cg05040219 GLIS1 100492 0.27931 cg00807684 RBMS3; RBMS3; RBMS3 17055 0.27912 cg10536999 NFE2L3 200194 0.27826 cg22458832 396980 0.2773 cg09257635 GJC2 177820 0.27706 cg24576026 SEPT9; SEPT9 431206 0.27474 cg01999051 BRP44L 40997 0.27386 cg10820084 COL1A1 204937 0.27361 cg07696516 LIMCH1; LIMCH1; LIMCH1; 149907 LIMCH1; LIMCH1; LIMCH1; LIMCH1 0.27349 cg10937408 HRNBP3 206779 0.2732 cg07021447 ACTN1; ACTN1; ACTN1 137188 0.27261 cg13644549 C7orf50; C7orf50; C7orf50 252081 0.27247 cg26787787 467264 0.27222 cg10881749 205937 0.27192 cg24718015 STAT3; STAT3; STAT3 433677 0.27022 cg03780701 ADAM32 76382 0.26961 cg13735018 SYNJ2 254007 0.26932 cg19391924 HRNBP3 349887 0.26888 cg13551141 PSMB7 250097 0.2674 cg14370520 FAM188B 267054 0.26591 cg01660999 ANGPT1 34240 0.26415 cg13626830 RASGRF2 251743 0.26352 cg20441502 FXYD7; FXYD1; FXYD1 366782 0.26348 cg01833196 SH3PXD2A 37634 0.26334 cg00369056 7795 0.26334 cg13683667 252916 0.26327 cg19576241 352883 0.26302 cg21983607 390212 0.26214 cg03666350 74131 0.26137 cg05166871 SKAP1; SKAP1 102879 0.2612 cg15366684 ADAMTS2; ADAMTS2 284322 0.26116 cg25885684 451999 0.26059 cg17290488 C5orf45; C5orf45 316572 0.25763 cg19954341 T 359498 0.25735 cg20668662 SH3PXD2A 370194 0.25696 cg24657523 MYEF2 432522 0.25675 cg03537386 COL16A1 71519 0.25598 cg25616600 448034 0.25566 cg20201270 363196 0.25559 cg01229787 25802 0.25515 cg08145723 ST14 158133 0.25468 cg07878514 INSM1; INSM1 153203 0.25399 cg06189394 LRIG1 121568 0.25382 cg08830502 170348 0.25298 cg05979619 MERTK 117911 0.25278 cg16402635 CASP1; CARD16; CASP1; CASP1; 301579 CASP1; CASP1; CARD16 0.25223 cg17007374 311924 0.25189 cg26681770 PMEPA1; PMEPA1; PMEPA1; 465572 PMEPA1 0.25166 cg04649852 92984 0.25103 cg16282024 DERL1; DERL1 299433 0.25043 cg01392518 T 28927 0.24945 cg05590156 TRIO 110699 0.24922 cg24174557 TMEM49 425007 0.24886 cg00225902 LRIG1 4852 0.24875 cg03401875 ADAMTS2; ADAMTS2 68835 0.24859 cg23489226 413717 0.24854 cg15745401 P2RY6; P2RY6 290636 0.24785 cg24752267 434286 0.24696 cg09527270 POMC; POMC 182597 0.24687 cg00145961 NTRK3; NTRK3; NTRK3 3269 0.24685 cg15323840 SYNJ2 283724 0.24679 cg11261412 B3GNTL1 212263 0.24671 cg04723534 C2CD2 94311 0.2467 cg03771840 TRIM15 76209 0.24643 cg03472954 PRKAR1B; PRKAR1B; PRKAR1B; 70250 PRKAR1B; PRKAR1B; PRKAR1B 0.24643 cg23533513 MYO7A; MYO7A; MYO7A 414506 0.24628 cg19010441 MED12L; GPR171 344302 0.24604 cg06186245 TMEM45A 121509 0.24529 cg23834919 419111 0.24525 cg00037856 943 0.24513 cg27338607 476928 0.24455 cg05287372 C3orf64 105151 0.24329 cg14905634 TRHDE 277082 0.24298 cg11692307 PLCH2 219166 0.24275 cg04677410 MAML2 93491 0.24251 cg16561266 LOC146880; LOC146880 304457 0.24244 cg09461792 181455 0.24119 cg00548708 11644 0.24101 cg11120154 209834 0.24078 cg14587335 HRNBP3 271586 0.23936 cg09650180 GMEB2 184694 0.23799 cg09379935 P2RY6; P2RY6 180013 0.23797 cg21680719 FHL3 385790 0.23791 cg24917131 437034 0.23723 cg12097883 LOC146880; LOC146880 226317 0.23698 cg03558269 71975 0.2367 cg08870914 171157 0.23667 cg14501219 LOC146880; LOC146880 269672 0.2365 cg09180564 OLFM3 176500 0.23608 cg02477603 50448 0.23603 cg14260695 264921 0.23574 cg08613122 PRKAR1B; PRKAR1B; PRKAR1B; 166544 PRKAR1B; PRKAR1B; PRKAR1B 0.23559 cg25577130 CA4 447341 0.23548 cg08718098 168443 0.23462 cg17896243 326150 0.23435 cg09385667 PDZRN3 180096 0.2343 cg09529093 ANGPT1 182630 0.23254 cg10960920 PGCP 207207 0.23124 cg07107756 CARD14; CARD14 138866 0.23111 cg07480647 GPR153 145935 0.23044 cg11218619 211494 0.23008 cg05721365 LOC146880; LOC146880 113082 0.22965 cg21531685 PDZRN3 383375 0.22946 cg12854371 LOC146880; LOC146880 238254 0.22905 cg04028695 81035 0.22873 cg05665651 ANKRD11 112125 0.22861 cg09259235 177859 0.2273 cg15341866 283990 0.22729 cg03019360 61484 0.22691 cg19409546 350194 0.22689 cg26098164 BMP7 455309 0.22559 cg23965931 STOX2 421288 0.22486 cg27292547 475989 0.22459 cg10094238 ARHGAP27; ARHGAP27; 192273 ARHGAP27 0.22433 cg26938118 NEDD4L; NEDD4L; NEDD4L; 470085 NEDD4L; NEDD4L; NEDD4L; NEDD4L; NEDD4L; NEDD4L 0.22395 cg12741645 AEN 236560 0.22392 cg11189268 ARHGAP27; ARHGAP27 210952 0.22268 cg10481134 C2orf58 199061 0.22247 cg25213720 MXD3; MXD3 441707 0.22232 cg07357716 143726 0.22207 cg10975897 JARID2 207446 0.22204 cg10177197 DHCR24 193879 0.22183 cg26215428 PKD2 457374 0.2215 cg01451808 30240 0.22132 cg24186459 425188 0.2211 cg14910684 277182 0.21926 cg01040786 21929 0.21871 cg07146912 PDZRN3 139702 0.21843 cg01359469 TRIP4 28275 0.2181 cg07459478 VOPP1 145466 0.21793 cg06012804 118540 0.21771 cg25335841 443510 0.21765 cg26303870 ACTN1; ACTN1; ACTN1 458957 0.21683 cg01095004 23112 0.21596 cg13369952 JAKMIP2 246290 0.21555 cg26159368 456463 0.21526 cg10328583 PLEKHG5; PLEKHG5; PLEKHG5; 196553 PLEKHG5 0.21524 cg22041190 PKNOX2 391040 0.21505 cg13717446 LOC146880; LOC146880 253646 0.215 cg20134287 AUTS2; AUTS2 362245 0.21488 cg16755214 308115 0.21465 cg00599219 MEFV 12810 0.21458 cg13470462 BOC 248426 0.21391 cg13027183 JARID2 240842 0.21382 cg14467181 268995 0.21371 cg04674201 93425 0.2137 cg16936561 RAB11FIP5 310943 0.21339 cg13393580 MXRA8 246755 0.21294 cg00813162 ACTN1; ACTN1; ACTN1 17174 0.21281 cg21687563 TTC28 385895 0.21199 cg07076816 138253 0.21196 cg10195336 ARHGEF10 194213 0.21167 cg26588688 463998 0.21129 cg14524975 ITGB7 270223 0.21125 cg05373161 TMEM231; TMEM231; TMEM231 106877 0.21109 cg10283505 FUT4; FUT4 195763 0.2109 cg27190145 DAAM2 474406 0.21048 cg23403980 SMG6; SMG6 412406 0.21047 cg10734665 ATP10A 203498 0.2102 cg01071185 22591 0.20996 cg13313047 CABLES1; CABLES1; CABLES1 245295 0.20986 cg18325315 GTF2IRD1; GTF2IRD1 333329 0.2097 cg24478420 429606 0.20967 cg20489026 KCNJ9 367521 0.20958 cg09119854 AXIN2 175345 0.2095 cg02186748 COL1A1 44750 0.20938 cg08223717 EEPD1 159595 0.20902 cg17265829 FAT4 316130 0.20884 cg04158862 KIAA0247 83588 0.2087 cg01521220 MIR1203; SKAP1; SKAP1 31528 0.20851 cg20472384 DIP2C 367281 0.2085 cg01322214 C7orf31 27599 0.20824 cg22972806 LYPD6B 405136 0.20805 cg12531838 DIP2C 233187 0.20773 cg06946797 135711 0.20742 cg11394820 214445 0.2069 cg06132400 120606 0.20684 cg13505393 LRRC32; LRRC32 249183 0.20661 cg02931762 59687 0.20651 cg23367392 GLI3 411874 0.20651 cg21699330 NFE2L3 386040 0.20618 cg09532095 THUMPD2; THUMPD2 182672 0.20597 cg02955287 60173 0.20575 cg07980854 155098 0.20548 cg21838924 CLDN4 388015 0.20493 cg09703910 185605 0.20481 cg03179435 FRMD4A 64565 0.20458 cg25946605 CYS1 452893 0.20455 cg12473775 RHOD 232200 0.20401 cg05467716 LOC146880 108495 0.20331 cg18476176 CNTF; ZFP91-CNTF 335848 0.20322 cg18362448 SSBP4; SSBP4 333911 0.20314 cg19245980 347655 0.20291 cg27342781 476987 0.20279 cg08011255 B3GNTL1 155601 0.2027 cg25252585 FXYD7 442281 0.20218 cg08170227 ACTN1; ACTN1; ACTN1 158605 0.20196 cg01700462 C20orf123 34874 0.20185 cg08920174 172096 0.20181 cg06180729 LDLRAD3 121411 0.20165 cg03144232 STX1B 63872 0.20053 cg05302100 COL1A1 105438 0.20037 cg01572653 32559 0.20024 cg00509485 10852 0.20012 cg02077068 GPRC5B 42649 0.19965 cg08797704 169751 0.19946 cg25674613 448920 0.19907 cg14236519 C7orf50; C7orf50; C7orf50 264409 0.19873 cg09371059 179858 0.19866 cg07250758 VWCE 141804 0.19825 cg14463068 MYT1L 268912 0.19821 cg27638057 C18orf45 481936 0.19814 cg19764489 KCNQ1; KCNQ1 356206 0.19799 cg05501859 C11orf17; C11orf17 109151 0.19792 cg02108623 PRDM1 43306 0.19791 cg18229049 NXN 331759 0.1975 cg15557036 287330 0.19749 cg03284879 66524 0.19681 cg23899450 420132 0.19665 cg16896313 310257 0.19654 cg11738198 219981 0.19638 cg25104234 439983 0.19612 cg08863777 FUT4 171018 0.19591 cg03143849 CDKN1C; CDKN1C; CDKN1C 63866 0.19551 cg27608563 CMIP 481430 0.19548 cg15601264 288057 0.19518 cg25712088 DIP2C 449437 0.19493 cg14003265 TRAF2 259423 0.19481 cg16926213 310774 0.19467 cg15339026 283944 0.19466 cg16429975 ACOT7; ACOT7 302121 0.19451 cg19780308 MAML3 356489 0.19435 cg01741688 SH3RF3 35665 0.19412 cg15465501 285947 0.19412 cg08639948 167048 0.19403 cg12453623 231887 0.19394 cg19093370 PLD6 345512 0.19388 cg10331829 SLC1A2 196611 0.19382 cg01806382 37024 0.1935 cg20953052 MIR548F2; ERBB4; ERBB4 374498 0.19341 cg20917077 CPA5; CPA5; CPA5 373937 0.19321 cg16434331 SLC39A11; SLC39A11 302207 0.19286 cg06581409 128362 0.1925 cg13229078 243978 0.19228 cg07044938 137615 0.19221 cg22853713 CASZ1; CASZ1 403146 0.19142 cg23878906 419768 0.19138 cg10469520 198872 0.19133 cg24229188 HMG20B 425784 0.19107 cg27185501 474347 0.19077 cg03556869 UST 71956 0.19047 cg03179447 64567 0.18988 cg15457718 285805 0.18981 cg27169559 474039 0.1897 cg00660305 PRKAR1B; PRKAR1B; PRKAR1B; 13970 PRKAR1B; PRKAR1B; PRKAR1B 0.1891 cg20142501 NXN 362369 0.18892 cg15298286 C17orf72 283380 0.18871 cg25954269 453043 0.18845 cg25418528 P2RX6; P2RX6 444919 0.18829 cg27132535 473446 0.18828 cg15449664 THY1 285660 0.18804 cg09109656 175197 0.18788 cg04070601 FMNL3; FMNL3 81748 0.18776 cg20882260 CACNA1C; 373464 0.18756 cg18267489 CD93 332434 0.1875 cg20463302 SH3D20 367133 0.18746 cg22020227 OLFML3 390677 0.18628 cg11419575 214920 0.18581 cg23369564 PLEKHO1 411901 0.18537 cg04768998 WIPF1; WIPF1 95158 0.18526 cg06605053 128746 0.18519 cg05008070 DACT1; DACT1 99885 0.18519 cg16030113 295289 0.18514 cg00472879 SORBS1; SORBS1; SORBS1; 10022 SORBS1; SORBS1; SORBS1; SORBS1 0.18466 cg14832378 275849 0.18464 cg27438889 TACC2; TACC2; TACC2; TACC2 478571 0.18403 cg04098052 82284 0.184 cg26275647 MDFIC; MDFIC 458453 0.18384 cg05757757 113669 0.18333 cg01198994 MXRA8 25206 0.1833 cg16104139 296436 0.18322 cg09868374 188450 0.18317 cg17797591 AXIN2 324404 0.18247 cg00250409 5354 0.18239 cg09976669 SWAP70 190212 0.18236 cg22231400 SLC17A7 393823 0.18227 cg02351674 48045 0.18188 cg11676636 ARHGAP22 218912 0.18152 cg00831127 EPHB2; EPHB2 17525 0.18147 cg14054883 SYK; SYK; SYK; SYK 260571 0.1814 cg05147262 ENAM 102478 0.1812 cg21242079 ADAMTS7 379397 0.18059 cg26523175 PDZK1IP1 462775 0.18031 cg04778236 SPSB1 95348 0.18026 cg01820962 NT5DC1 37371 0.18025 cg12315995 229820 0.17993 cg17250262 LBH 315917 0.17965 cg14227785 264238 0.17877 cg10882304 TACC2; TACC2; TACC2; TACC2 205944 0.17828 cg07047570 INSM1; INSM1 137657 0.17808 cg07286123 CD93 142424 0.17794 cg14089493 261291 0.17787 cg07997634 SLC25A13; SLC25A13; SLC25A13 155378 0.1776 cg18628732 338265 0.17747 cg12239557 TACC2; TACC2 228662 0.17737 cg06376402 INPP5A 124706 0.17726 cg09642857 184563 0.17704 cg17099048 COL22A1 313414 0.17689 cg10819733 204928 0.17667 cg26477792 462022 0.17575 cg00373436 TAGLN3; TAGLN3; TAGLN3 7897 0.17567 cg15029402 279170 0.17558 cg19080233 345285 0.17527 cg00157016 PFN4 3525 0.17525 cg02278646 ANO6; ANO6; PLEKHA9; ANO6 46492 0.17489 cg14684457 NFE2L3 273413 0.17474 cg09125999 DSCAML1 175477 0.17462 cg04940251 98587 0.17444 cg07135032 LMX1A 139425 0.17437 cg03491895 70579 0.17348 cg07459019 145455 0.17324 cg03762242 GAS7; GAS7; GAS7 76010 0.17305 cg23585686 415170 0.17287 cg00400827 8476 0.17285 cg02284273 FRMD4A 46611 0.17232 cg03560973 POMC; POMC 72034 0.17213 cg22304543 394846 0.17212 cg24147392 LOC440461 424521 0.17206 cg14251267 ZBTB46 264704 0.1718 cg20052079 JARID2 360990 0.17144 cg19161251 LMO4 346462 0.17138 cg01364478 PRRX1; PRRX1 28365 0.17129 cg14255700 IPPK 264808 0.17113 cg07067577 SH3D20 138069 0.17078 cg27345989 NXN 477039 0.17062 cg21029769 ST14 375731 0.17054 cg26821721 KLHL29 467947 0.17025 cg13890428 257013 0.17003 cg15134506 USP54 280991 0.17002 cg21142398 GLIS1 377429 0.16954 cg08533336 USP2; USP2 165172 0.16947 cg18006637 FAM13A; FAM13A 327818 0.16924 cg23692500 417116 0.16901 cg01093786 MAML2 23085 0.169 cg00285394 SQLE 6012 0.16825 cg20673819 C6orf176; C6orf176 370286 0.16804 cg03676578 74324 0.168 cg21946195 ATOH8 389751 0.16791 cg10346364 LOC100130987; CLCF1; CLCF1 196856 0.16785 cg08935841 172361 0.16779 cg02216727 GJD3; GJD3 45257 0.16775 cg13088556 241806 0.16685 cg20860726 MYT1L 373230 0.16671 cg11927233 NPM1; NPM1; NPM1 223346 0.16655 cg17842189 TBC1D22A 325238 0.16649 cg23508201 414035 0.16631 cg18772205 KLHL6 340567 0.16625 cg18402987 334557 0.16616 cg10350880 EPHB4 196929 0.16606 cg03943115 SPRR2D 79303 0.16531 cg03967266 79784 0.16529 cg09099242 MMRN2 175043 0.16453 cg08302650 LRRC24; LRRC14 161144 0.1644 cg08049717 AMOTL2 156270 0.16429 cg03764092 TBXAS1; TBXAS1; TBXAS1; 76037 TBXAS1; TBXAS1; TBXAS1 0.16421 cg07275179 ATXN7; ATXN7 142217 0.16413 cg05529123 109677 0.16411 cg14103872 OLFML2A 261610 0.16404 cg19996406 360145 0.16364 cg16568084 304587 0.16364 cg13165983 242911 0.16332 cg00409696 8667 0.16319 cg11733958 MPRIP; MPRIP 219898 0.16308 cg08458711 BSND 163781 0.16261 cg18861112 WDFY2 342032 0.16254 cg21293455 380108 0.16247 cg06526620 FUT4 127302 0.16242 cg12303623 USP54 229638 0.16225 cg06501835 126864 0.16225 cg05243389 MYEF2 104339 0.1619 cg15372959 TACC2; TACC2; TACC2; TACC2 284406 0.16187 cg08879365 171347 0.16183 cg00802386 16940 0.16175 cg16224163 LPP 298398 0.16119 cg02276070 ARSI 46431 0.16116 cg00702126 VWA1; VWA1 14846 0.1611 cg04674421 93433 0.16107 cg08333931 SH3D20 161705 0.16089 cg27177158 474183 0.16083 cg04948016 98755 0.1607 cg19144071 346231 0.1607 cg10628617 SCUBE1 201790 0.16063 cg19542987 ARMC3 352374 0.16049 cg27265404 475561 0.16007 cg03756522 75895 0.15976 cg19856845 RIN3 357783 0.15961 cg09492169 ARHGAP27; ARHGAP27 181962 0.15953 cg27458177 478888 0.1592 cg03303857 GRIK4 66884 0.15887 cg11845549 221989 0.15871 cg15246712 EBF2 282686 0.15867 cg08009487 KRT4; KRT4 155576 0.15857 cg21429516 381785 0.15832 cg13552867 KCNJ9 250134 0.15799 cg22044408 391096 0.1579 cg13440947 GFRA1; GFRA1; GFRA1 247730 0.15763 cg14363469 266959 0.15736 cg08005872 155513 0.1573 cg00094585 2207 0.15729 cg04944536 98671 0.15686 cg04658243 RPTOR; RPTOR 93139 0.15641 cg11454459 215415 0.15627 cg11084571 KANK4 209299 0.15582 cg26227310 TLX1NB 457602 0.15574 cg05541311 109868 0.15565 cg00095431 2233 0.15534 cg08548284 165445 0.15493 cg03919650 MEFV 78874 0.15488 cg05786009 114191 0.15461 cg04024827 FLJ12825 80948 0.15448 cg15653254 289035 0.1544 cg04649598 ODZ4 92979 0.15426 cg08615354 166583 0.15398 cg05909702 116481 0.15394 cg08785724 169563 0.15382 cg00990769 MATN2; MATN2 20836 0.15381 cg08734931 FRMD4A 168749 0.15277 cg05277096 PDZRN3 104972 0.15274 cg25169706 ST5; ST5; ST5 A441040 0.15273 cg24572745 BOC 431168 0.15262 cg21176130 HLA-E 378075 0.15251 cg00514353 PCDH1 10956 0.15225 cg25515269 ITGA4 446437 0.15211 cg25653204 FPR2 448621 0.15196 cg25349820 443748 0.15173 cg11401293 COL6A1 214569 0.15074 cg14036069 NEK6; NEK6; NEK6; NEK6 260162 0.15059 cg14110685 261719 0.15038 cg11673092 ARMC3 218848 0.15033 cg24098326 TACC2; TACC2; TACC2; TACC2 423638 0.15015 cg17783086 LOC146880; LOC146880 324191 0.14948 cg17332379 LOC146880; LOC146880 317320 0.14904 cg26697605 465886 0.1489 cg16637224 305900 0.14883 cg19793499 AUTS2; AUTS2 356717 0.14862 cg13698865 COL5A1 253254 0.14823 cg14955976 277886 0.1482 cg24537942 KANK4 430673 0.14803 cg22958076 404890 0.14799 cg02079741 POMC; POMC 42708 0.14778 cg12055422 225496 0.14773 cg13947999 258288 0.1477 cg13121428 TGFB3 242270 0.14752 cg25651608 448592 0.14738 cg03573945 EBF2 72279 0.14713 cg07922154 ARG2 154039 0.14713 cg06516502 127100 0.14685 cg26719062 466225 0.14673 cg00020474 497 0.14661 cg07015554 137042 0.1466 cg02095937 TRIM59 43034 0.14648 cg22111167 PTPRJ; PTPRJ 392026 0.14639 cg16892553 PRR15L; PRR15L 310202 0.14634 cg00512602 SH3D20 10920 0.14595 cg27359636 477238 0.14577 cg23325335 411144 0.14539 cg15671996 TRIM15 289301 0.14536 cg14725580 C6orf106; C6orf106 274100 0.14511 cg13724550 FGF1; FGF1; FGF1; FGF1; FGF1; 253793 FGF1; FGF1 0.14497 cg19399514 RFTN1 349989 0.14495 cg11790417 220854 0.14482 cg15152115 281271 0.1445 cg11474182 CNTNAP3 215691 0.14435 cg05123976 101999 0.1441 cg03009240 FZR1 61309 0.14404 cg09359810 FRMD6 179634 0.14388 cg23931919 420690 0.14388 cg10321236 MYO7A; MYO7A; MYO7A 196418 0.1436 cg11222217 CASZ1; CASZ1 211555 0.14337 cg21487363 FOXP1; FOXP1 382660 0.14296 cg23522194 PLA2G4C; PLA2G4C; PLA2G4C 414285 0.14295 cg26871180 468843 0.14284 cg16139517 CNTN4 297000 0.14275 cg15371815 CRIM1 284394 0.14258 cg24118856 PPAN-P2RY11; P2RY11 423968 0.14258 cg15400997 PLXNC1 284893 0.14257 cg26950531 DPF1; DPF1; DPF1 470304 0.14252 cg23270841 PARD3B; PARD3B; PARD3B 410288 0.1418 cg00542975 CLASP1; CLASP1; CLASP1 11524 0.14168 cg06644998 129612 0.14118 cg04567302 SLC44A4 91475 0.14106 cg26002568 453787 0.14087 cg04289208 LGR6; LGR6 86168 0.14072 cg13085980 PLXNC1 241773 0.14055 cg18124852 329967 0.14042 cg13214162 243716 0.14037 cg07103748 138784 0.14016 cg04756252 SLA; SLA; TG; SLA 94952 0.13944 cg17253459 OLFML3 315956 0.1392 cg04601228 AUTS2; AUTS2 92149 0.13894 cg10005270 C10orf90 190712 0.13871 cg13948956 258313 0.1387 cg01211852 25460 0.13832 cg01654566 34124 0.13826 cg09528501 182620 0.13793 cg21688152 B3GNTL1 385901 0.13778 cg25472296 DOCK1 445774 0.13777 cg21951457 TACC2; TACC2; TACC2; TACC2 389827 0.13769 cg08102611 GAS7 157232 0.13766 cg13008631 IRS1 240565 0.13745 cg20535425 368163 0.13721 cg04689880 93734 0.13713 cg04768479 95139 0.13705 cg20438277 CD93 366734 0.13663 cg10301879 C6orf105; C6orf105 196052 0.13653 cg19582200 SCUBE1 352974 0.13647 cg25967170 453238 0.13638 cg06620993 SH3PXD2A 129075 0.13588 cg12812165 NIN; NIN; NIN 237654 0.13581 cg13053992 241251 0.13547 cg14598213 NGFR 271799 0.13528 cg19193956 346894 0.13503 cg06021990 FLT1 118695 0.13498 cg01715025 RNF115 35160 0.13498 cg05787209 STX1B 114223 0.13486 cg14206273 CASZ1; CASZ1 263709 0.13472 cg25599473 SMOC2; SMOC2 447739 0.13467 cg23200466 FBXW11; FBXW11; FBXW11 408900 0.13452 cg09868780 LVRN 188458 0.13444 cg05246303 ITGA4 104393 0.13439 cg03213259 TRADD 65187 0.13426 cg07067982 SLC43A3; SLC43A3; SLC43A3; 138080 SLC43A3 0.13383 cg24960118 PKHD1; PKHD1 437734 0.13373 cg06942124 135615 0.13373 cg06443678 125849 0.13342 cg18674487 338954 0.13337 cg11268280 212378 0.13318 cg08681473 COL1A1 167753 0.13306 cg03143046 63849 0.13304 cg06842253 133582 0.13286 cg26363935 NWD1 460109 0.13282 cg24250588 CLDN19; CLDN19 426051 0.13272 cg01579600 32722 0.13255 cg20567368 368674 0.13204 cg20054157 SFTA1P 361020 0.13169 cg16052198 FPR2 295658 0.13115 cg12888521 238770 0.13102 cg21322248 PSTPIP1 380448 0.13082 cg23418965 PKNOX2 412666 0.13073 cg10193441 HRNBP3 194174 0.13072 cg25566312 TGFBI 447171 0.13053 cg00334821 LIMK1 7073 0.13046 cg18132405 LEPREL1; LEPREL1 330109 0.13036 cg13893782 PDE7B 257077 0.13034 cg12575928 GAS2 233842 0.13018 cg03669949 DDX43; DDX43 74206 0.13012 cg19528338 BMP2 352128 0.13001 cg15878619 TUBB 292734 0.1298 cg07187808 KCNJ9 140601 0.1297 cg06641357 129537 0.12946 cg06618298 MYO10 129012 0.12929 cg04332927 87001 0.12922 cg11041060 SMOC2; SMOC2 208580 0.12875 cg19264571 APCDD1 347991 0.12861 cg00832547 RAGE 17556 0.12794 cg05376469 106960 0.1279 cg10331500 TGFA; TGFA 196606 0.12762 cg06983052 LRRC8D; LRRC8D 136433 0.12762 cg12019475 224847 0.12739 cg16900264 310326 0.12733 cg01055696 22251 0.12706 cg00652846 BOC 13828 0.12699 cg17265419 ITGA4 316124 0.12692 cg07570498 PHC2; PHC2 147621 0.12659 cg17504145 CRYBB2 320177 0.12646 cg00872354 18374 0.12628 cg08504407 HRNBP3 164658 0.12625 cg19072083 345194 0.12581 cg22660447 C16orf7 399970 0.12507 cg18169095 LAD1 330752 0.12494 cg24167667 424904 0.12488 cg02281167 TRIM15 46550 0.12477 cg18771659 SPRR1B 340554 0.12456 cg13197521 SPSB1 243430 0.12441 cg23733123 MARVELD1; MARVELD1 417794 0.12439 cg19681793 THBS2 354639 0.12435 cg22373687 395848 0.12435 cg01838728 37759 0.12422 cg03083517 COL22A1 62783 0.12417 cg01149239 MFI2; MFI2 24207 0.12417 cg05593669 110779 0.12379 cg00348891 7377 0.12362 cg19125999 C1orf172 345998 0.12359 cg26221801 C20orf195 457494 0.12334 cg01325188 BANP; BANP 27654 0.12301 cg08066024 NRXN1; NRXN1 156540 0.12289 cg04344730 DAB1 87247 0.12282 cg03467555 70136 0.12254 cg22124564 AMZ1 392246 0.12211 cg09882901 188677 0.1218 cg26472922 461941 0.12177 cg22810790 CA4 402441 0.1217 cg20396299 366115 0.1215 cg01399485 CASZ1; CASZ1 29081 0.12144 cg27423739 478314 0.12144 cg11857093 222224 0.12129 cg04004513 SKAP1; SKAP1 80529 0.12105 cg16731157 RCAN3 307717 0.12064 cg04757806 FUT4 94983 0.12052 cg10930901 206696 0.12044 cg09728333 185957 0.12032 cg22159835 NRXN2; NRXN2; NRXN2 392801 0.12007 cg10168635 C2orf88; C2orf88; C2orf88; C2orf88 193705 0.1198 cg12891678 238813 0.11957 cg06382546 LRP1B 124829 0.11923 cg16118803 MOG; MOG; MOG; MOG; MOG; 296688 MOG; MOG; MOG; MOG; MOG; MOG 0.11879 cg24642523 HSPA2 432315 0.11842 cg05280131 FAM128A; LOC150776 105029 0.11823 cg23693749 417137 0.11821 cg25255713 EVPLL 442316 0.11814 cg23257225 ADORA1; ADORA1 410054 0.11813 cg12536891 CLPB 233264 0.11771 cg08922201 SYT7 172124 0.11744 cg16274954 DPCR1 299319 0.11728 cg04011829 SLCO4A1 80684 0.11703 cg16143578 ROBO4; ROBO4 297069 0.11698 cg09966895 ODZ4 190045 0.11691 cg24113950 423878 0.11646 cg19119609 345922 0.11612 cg05663064 COL6A1 112083 0.1161 cg19388972 349838 0.11582 cg05979400 LOC100128731 117903 0.11568 cg01311341 KIAA1671 27416 0.11546 cg06825512 APCDD1 133201 0.11466 cg26292150 ZDHHC19 458748 0.1146 cg06282247 123104 0.11404 cg17438457 319053 0.11398 cg06427611 PARVB 125571 0.11372 cg11386098 SYT7 214308 0.11358 cg13188382 243299 0.11315 cg03409151 ALDH7A1 68983 0.11311 cg18771300 RHOJ 340543 0.11298 cg15320349 283665 0.11293 cg03840259 GRAP2 77400 0.11242 cg03779072 76349 0.11235 cg00795584 16819 0.11176 cg06938705 135549 0.11144 cg04263215 NDUFS2; ADAMTS4 85649 0.11144 cg09296742 178512 0.11107 cg18804920 CNTNAP2 341118 0.11103 cg12835313 CACNA2D3 237974 0.11083 cg07157030 RHOJ; RHOJ 139948 0.11062 cg19725553 BLVRA 355438 0.11045 cg13777287 CNKSR3 254763 0.11016 cg26048630 PRRX1; PRRX1 454529 0.10972 cg02666837 54361 0.10966 cg11073796 209086 0.10936 cg04554928 TRIM15 91220 0.10888 cg17963461 327141 0.1087 cg15580417 KCNJ9 287721 0.10863 cg21602520 BCL2; BCL2 384588 0.10849 cg21817750 MRPS27 387694 0.10849 cg21306949 380293 0.10796 cg09126995 PHC2; PHC2 175501 0.10783 cg23931734 CA12; CA12 420686 0.10741 cg03679504 LRRC2; LRRC2; TDGF1 74369 0.10704 cg05272790 TMPRSS13 104903 0.10702 cg10512203 COL9A2 199691 0.10677 cg17848515 SMPD4; SMPD4; SMPD4; SMPD4; 325326 SMPD4; SMPD4; SMPD4; FAM128B 0.10643 cg06824523 PLCH2 133178 0.10623 cg24833464 KRTAP3-1 435563 0.1062 cg01619846 UHRF1; UHRF1 33506 0.10589 cg00089821 2084 0.1058 cg02506908 HPD 51094 0.10525 cg24248680 FAM24B 426016 0.10495 cg22261895 PLBD1 394295 0.10453 cg25638443 ST8SIA1 448399 0.10437 cg08770647 ROBO4 169334 0.10378 cg10663897 202375 0.10325 cg09075327 PSD3 174665 0.10321 cg11505113 VASH2; VASH2; VASH2 216106 0.10291 cg24251135 USP38 426061 0.1029 cg26824174 OLFML3 467994 0.10284 cg11912513 223148 0.10264 cg03887520 78268 0.1024 cg21674153 B4GALT6 385733 0.10236 cg17147466 314205 0.10181 cg21931864 SH3D20 389527 0.10134 cg09469870 181594 0.10132 cg06294384 123314 0.10127 cg22693493 400543 0.10127 cg05492433 COL22A1 108970 0.10066 cg06915112 135102 0.10002 cg14320626 266136

TABLE 7 SEQ OA − RA Locus Associated gene ID No. −0.10022 cg00490976 10388 −0.10038 cg00082140 1884 −0.10076 cg04080530 81955 −0.10083 cg25035059 CHD7 438996 −0.10092 cg09944434 189753 −0.10117 cg14538532 PBX2 270543 −0.10144 cg27165033 473953 −0.10204 cg03110300 CPLX4 63236 −0.10239 cg14729148 CUGBP2; CUGBP2; CUGBP2; 274152 CUGBP2 −0.10249 cg15730121 DLGAP4; DLGAP4; DLGAP4 290375 −0.10256 cg24037389 SCARA5 422606 −0.10268 cg20933239 374167 −0.10274 cg10627737 COL4A2 201776 −0.1028 cg19006947 PLCB3 344239 −0.10299 cg08613239 166546 −0.10305 cg15645757 UBE2Q1 288883 −0.10316 cg19056664 CLPTM1L 345033 −0.10356 cg03741475 75606 −0.10398 cg26332797 CTTNBP2 459481 −0.10398 cg07447015 ANKRD11 145230 −0.10414 cg06823060 CMIP; CMIP 133147 −0.10436 cg05150973 EHD1 102541 −0.10453 cg05587232 C7orf50; C7orf50; C7orf50 110657 −0.10463 cg26949393 AGAP3 470288 −0.10493 cg07266910 ZMAT3; ZMAT3 142085 −0.10509 cg01993576 SLC29A1; SLC29A1 40885 −0.10514 cg22907277 C7orf50; C7orf50; C7orf50 404094 −0.10515 cg12544243 GRIN3B 233359 −0.10541 cg23078123 GPR177 407010 −0.10541 cg09545918 COL8A1; MIR548G; COL8A1 182887 −0.1056 cg15067032 279802 −0.10586 cg24781973 FMN1 434762 −0.1059 cg07576033 C16orf11 147740 −0.10596 cg02256384 46036 −0.10602 cg08371643 CA4 162329 −0.10751 cg10985158 NAV1 207637 −0.10791 cg06531624 127430 −0.10813 cg25570929 COLEC12 447236 −0.1085 cg00997264 20997 −0.10866 cg18494399 SLC1A2 336159 −0.10876 cg21406461 IFI16 381503 −0.10879 cg24395452 SPATA18 428258 −0.109 cg10903916 ASAP2; ASAP2 206293 −0.1093 cg06330375 TSC2; TSC2; TSC2 123883 −0.10957 cg00779797 CAPN2; CAPN2 16482 −0.11024 cg18145505 GREM1 330327 −0.11042 cg26883033 469090 −0.11044 cg25334834 VGLL4; VGLL4; VGLL4; VGLL4 443491 −0.11048 cg18565130 C7orf50; C7orf50; C7orf50 337296 −0.11085 cg06067955 MYPN 119469 −0.11124 cg11147154 FLNC; FLNC 210249 −0.11125 cg14473823 269143 −0.11142 cg18324583 333319 −0.11152 cg24917359 C1QTNF1; C1QTNF1; C1QTNF1 437035 −0.11155 cg22346073 CLASP1; CLASP1; CLASP1 395428 −0.1116 cg04958191 ASPH; ASPH; ASPH; ASPH; 98926 ASPH −0.11187 cg12160741 BRF1 227383 −0.11193 cg01821635 37390 −0.11205 cg03131767 ABCB9; ABCB9; ABCB9 63648 −0.11209 cg26576937 EBF4 463815 −0.11214 cg15142477 RNF165 281126 −0.1125 cg13893427 257066 −0.11262 cg17527422 C12orf68; C12orf68 320633 −0.1128 cg08642731 C10orf71; C10orf71 167107 −0.11281 cg15006627 GPRC5A 278771 −0.11292 cg12626411 PRG4; PRG4; PRG4; MIR548F1; 234784 PRG4 −0.1131 cg22851557 PRDM16; PRDM16 403103 −0.11319 cg26803803 DNMT3A; DNMT3A; MIR1301; 467585 DNMT3A −0.11355 cg18746826 SCARA5 340084 −0.11368 cg26186331 DAB2 456925 −0.11378 cg15696968 KIAA1949; NRM; KIAA1949 289755 −0.11389 cg11014810 SH3PXD2A 208137 −0.11393 cg14190889 HLA-H 263376 −0.11407 cg17655346 CACNA2D3 322379 −0.11414 cg24777564 ADAMTS12 434703 −0.11439 cg04156383 PDE4DIP; PDE4DIP; PDE4DIP; 83534 PDE4DIP −0.11448 cg02296376 MIR1286; RTN4R 46872 −0.11454 cg00145875 3263 −0.11464 cg21862126 388401 −0.11468 cg12181407 227738 −0.11476 cg21733013 RAPGEF5 386423 −0.11485 cg25379549 ADARB2 444296 −0.11508 cg07815521 MIR641; AKT2 152123 −0.11512 cg03037030 TNF 61825 −0.11515 cg14930864 YWHAQ 277519 −0.11516 cg23980760 ACCSL; ACCSL 421559 −0.11517 cg26858414 CDSN; PSORS1C1 468630 −0.11524 cg10831642 SH3PXD2A 205142 −0.11537 cg03901836 C2orf57 78575 −0.11539 cg16705287 POLR2E 307214 −0.11541 cg05557262 FAM180A 110128 −0.11544 cg03860038 77780 −0.11546 cg20989591 C7orf50; C7orf50; C7orf50 375141 −0.1157 cg03627771 GRAMD1B 73371 −0.1158 cg02145701 BANP; BANP 43968 −0.11616 cg13093380 ALK 241873 −0.11621 cg10239022 GPR133 195020 −0.1167 cg17753942 323769 −0.11676 cg21540399 PTPRG 383531 −0.11688 cg16538359 304039 −0.11692 cg01320211 SEMA6D; SEMA6D; SEMA6D; 27561 SEMA6D; SEMA6D; SEMA6D −0.11693 cg02020821 PPP2R5C; PPP2R5C; PPP2R5C; 41450 PPP2R5C; PPP2R5C −0.11698 cg06873401 LHFPL2 134232 −0.11705 cg15671083 UCN3 289292 −0.1173 cg00102093 2393 −0.11732 cg21356710 MFSD2B 380867 −0.11738 cg21205282 378649 −0.11761 cg07723948 OSGIN1; OSGIN1; OSGIN1 150463 −0.1177 cg16500916 303286 −0.11772 cg24634422 SLC1A2 432160 −0.11788 cg06755262 131696 −0.11803 cg24698488 MMP14 433309 −0.11805 cg01675953 MCF2L; MCF2L 34463 −0.11814 cg15547672 RPTOR; RPTOR 287142 −0.11827 cg23850174 419365 −0.1184 cg05429527 107954 −0.11845 cg27437823 MAP3K14 478553 −0.11865 cg15470365 SORBS2; SORBS2; SORBS2; 286032 SORBS2; SORBS2 −0.1187 cg24577455 PRKCZ; PRKCZ; PRKCZ 431245 −0.11873 cg18458739 BCAS3; BCAS3 335553 −0.11874 cg11335264 CAPZB 213463 −0.11901 cg00961940 TIMP2 20220 −0.11901 cg04712892 NRAP; NRAP 94119 −0.11917 cg27582168 FANCA 481016 −0.11931 cg17294136 CACNA2D1 316631 −0.11937 cg13932122 257954 −0.11937 cg10637688 201971 −0.11938 cg05384139 PITPNM2 107123 −0.11954 cg04554240 ESYT3 91205 −0.11954 cg22429169 ZNF335 396572 −0.11965 cg03917297 78835 −0.11967 cg19408740 IGSF8 350178 −0.11986 cg09745791 CTRB1 186257 −0.12011 cg06521562 JRK; JRK 127195 −0.12013 cg19678029 KCNQ1OT1; KCNQ1; KCNQ1 354576 −0.12018 cg09915421 189251 −0.12024 cg15827092 291857 −0.12026 cg25827666 SH2D2A; SH2D2A; NTRK1; 451242 NTRK1; SH2D2A; SH2D2A; SH2D2A −0.12033 cg14166209 262818 −0.12033 cg06647382 PDK2 129663 −0.12099 cg13543096 LOC100271831; GDPD3 249930 −0.12099 cg06679262 130241 −0.12103 cg05514932 RETSAT 109417 −0.12105 cg22624391 399439 −0.12109 cg19480385 351330 −0.12113 cg08325842 ZFP91; ZFP91-CNTF 161555 −0.12122 cg15368872 KLRK1 284353 −0.12175 cg27313492 WFIKKN1 476470 −0.12203 cg05182583 BAT2 103165 −0.12205 cg22193013 CHRNA7 393284 −0.12211 cg16209444 ACOX2 298173 −0.12214 cg20577102 368824 −0.12217 cg06326425 GPC6 123816 −0.1226 cg24353272 RRP15 427604 −0.12271 cg06306791 123517 −0.12281 cg11253913 CALD1; CALD1; CALD1; 212154 CALD1; CALD1 −0.12285 cg08352422 161993 −0.12293 cg16044109 HEG1 295491 −0.12298 cg23198815 408873 −0.12305 cg23922753 420530 −0.12305 cg15442583 CDGAP 285507 −0.12317 cg02248749 TNXB 45883 −0.12323 cg13455257 TMOD4 248067 −0.12337 cg00740389 ITGB7 15652 −0.12369 cg08448751 SEMA3G 163578 −0.1237 cg20663448 FILIP1 370104 −0.12374 cg00819141 17296 −0.12375 cg00161791 3633 −0.12376 cg01569083 TNF 32491 −0.12392 cg00254017 MAP3K1 5441 −0.12398 cg24885556 ITGA7 436558 −0.12399 cg21082141 PRDM8 376504 −0.12415 cg01785514 TATDN3; TATDN3; TATDN3; 36554 TATDN3; TATDN3 −0.12442 cg14771877 C17orf99 274788 −0.12455 cg02866149 C20orf117 58258 −0.12464 cg02667577 WIPI2; WIPI2; WIPI2; WIPI2; 54375 WIPI2 −0.12507 cg19973338 C17orf99 359782 −0.12517 cg13709561 SCARA5 253479 −0.12585 cg14118850 HPCAL1; HPCAL1 261879 −0.1259 cg03728674 75338 −0.12611 cg25340361 COMMD1 443580 −0.12613 cg07347019 143506 −0.12631 cg16000393 TNK2; TNK2 294736 −0.12649 cg02898239 58930 −0.12655 cg16323245 ZBTB20; ZBTB20 300173 −0.12655 cg00907661 ZDHHC20 19059 −0.12665 cg23986495 421674 −0.12691 cg13720395 YWHAG 253710 −0.12696 cg00643876 TBC1D24 13650 −0.12697 cg14781826 BPTF; BPTF 275014 −0.12748 cg01476807 FBXO30 30709 −0.1277 cg19659642 CD9 354321 −0.12785 cg21455901 CRYL1 382161 −0.1279 cg01876531 PLXNA2 38448 −0.12817 cg03925072 78966 −0.12858 cg24267275 426255 −0.12861 cg10356210 KCNK3 197004 −0.1289 cg12145349 NAA40 227108 −0.12904 cg11820824 S100A16 221475 −0.12906 cg26989053 NTAN1 471015 −0.12914 cg09119494 E2F2 175337 −0.12918 cg18904855 342756 −0.12918 cg00572560 12164 −0.12919 cg25242423 RTBDN; RTBDN 442118 −0.12926 cg26745520 GRK5 466632 −0.12934 cg07044523 S100A5 137607 −0.12938 cg10048215 APOLD1; APOLD1 191451 −0.12949 cg10471743 198906 −0.12978 cg00767886 EHD4 16225 −0.12983 cg26562772 DUSP10; DUSP10; DUSP10 463554 −0.13012 cg00877958 18503 −0.13016 cg21230535 FTCD 379161 −0.13031 cg09664445 KIAA0664 184948 −0.13045 cg06708731 DBH 130785 −0.13094 cg11585805 217365 −0.13101 cg10626556 KIAA0406 201746 −0.13101 cg09982224 ALDH3B1 190313 −0.13118 cg09437523 181003 −0.13123 cg06769258 MFSD7 132014 −0.13123 cg05299140 105372 −0.1315 cg25735648 449823 −0.13164 cg20865778 TCIRG1; TCIRG1 373291 −0.13179 cg12450872 231834 −0.13196 cg00154554 RERE; RERE 3460 −0.1321 cg10006897 PCBP3; PCBP3 190741 −0.13211 cg14602234 271884 −0.13235 cg08917489 EYA4; EYA4; EYA4 172050 −0.13261 cg24088438 FERMT3; FERMT3; FERMT3; 423490 FERMT3 −0.13277 cg07325692 143137 −0.13288 cg08013109 ULK1 155629 −0.13289 cg09337391 ZMYND8; ZMYND8; ZMYND8 179281 −0.13298 cg12430302 SPSB1 231458 −0.13311 cg22912818 TMCO3 404171 −0.13319 cg08338281 WIBG 161768 −0.13321 cg10097651 192354 −0.13345 cg08122070 NADK 157631 −0.13393 cg10723746 SPPL2B; SPPL2B 203334 −0.13398 cg21656522 385493 −0.134 cg24598094 SLC30A1 431596 −0.13423 cg03466066 70093 −0.13424 cg19503826 EPN1; EPN1; EPN1 351690 −0.13442 cg18330041 YWHAH 333416 −0.13456 cg25707745 449371 −0.13486 cg09018904 ANO10 173744 −0.13517 cg07908868 PLXNA2 153755 −0.13522 cg01364674 28371 −0.13527 cg24995976 PEAR1 438225 −0.13549 cg17802464 SEC14L3 324476 −0.13562 cg23941016 TBC1D2B; TBC1D2B 420855 −0.13568 cg14504636 AP2A2 269745 −0.13571 cg17846466 MCOLN2 325303 −0.13574 cg16950726 NLGN2 311097 −0.13588 cg07466788 SLC16A3; SLC16A3; SLC16A3 145619 −0.13613 cg00767135 ODZ3 16210 −0.13616 cg01336162 TGFBR3 27842 −0.13632 cg05007126 SDCBP2 99869 −0.13637 cg12045511 EHD4 225319 −0.13667 cg18028470 PIGV 328228 −0.13671 cg15773893 DOCK10 291034 −0.13693 cg05652528 DNMT3A; DNMT3A; DNMT3A; 111855 MIR1301 −0.13703 cg19931529 UGP2; UGP2 359121 −0.1372 cg22488568 SLC9A1 397378 −0.13723 cg14904034 HPCAL1; HPCAL1 277047 −0.13747 cg27027230 ARID5B 471633 −0.1377 cg06607384 C14orf159; C14orf159; C14orf159; 128776 C14orf159; C14orf159 −0.13773 cg09766355 NPL 186590 −0.13778 cg17015522 C1QTNF1; C1QTNF1; C1QTNF1 312055 −0.13789 cg19494960 RPTOR; RPTOR 351529 −0.13793 cg07366462 ADCY5 143859 −0.138 cg04075247 LGALS12; LGALS12; LGALS12; 81844 LGALS12; LGALS12 −0.13801 cg01174811 PDE4D; PDE4D; PDE4D 24728 −0.13825 cg15536489 C7orf50; C7orf50; C7orf50 286952 −0.13832 cg00622170 C4orf10; NOP14 13248 −0.13853 cg08743794 KIAA1949; NRM; KIAA1949 168897 −0.13873 cg21370522 TNF 381016 −0.13878 cg06047674 FRMD4A 119120 −0.13896 cg12225794 228457 −0.13921 cg05905731 116408 −0.13924 cg03407594 MUC6 68950 −0.13938 cg26605914 SKI 464218 −0.1394 cg07359991 HSD3B7; HSD3B7; HSD3B7; 143753 SETD1A −0.13946 cg14780449 274978 −0.13949 cg16843799 FLJ39653; FLJ39653 309488 −0.13957 cg26805263 TNFRSF19; TNFRSF19 467622 −0.13961 cg13460740 MGC16703; P2RX6; P2RX6 248181 −0.13977 cg05488681 108898 −0.13998 cg17810878 ANO6; ANO6; ANO6 324639 −0.14009 cg12416561 C4orf22 231221 −0.14014 cg03649589 CSGALNACT1; CSGALNACT1; 73790 CSGALNACT1 −0.14031 cg07877964 USP7 153196 −0.14044 cg17499955 320108 −0.14047 cg17407629 PAM; PAM; PAM; PAM 318547 −0.14048 cg04305228 MICAL3 86473 −0.14066 cg24499411 TNS3 429956 −0.14066 cg17125990 313833 −0.14069 cg16608018 305379 −0.14074 cg15053322 SEC14L3 279556 −0.14077 cg11263420 FCGRT; FCGRT 212295 −0.14081 cg11437140 TIMP2 215182 −0.14083 cg07328796 143190 −0.14111 cg00528616 ZNRF1 11235 −0.14116 cg13619044 C7orf41 251590 −0.14119 cg03277153 66388 −0.14128 cg22321646 LZTS1 395060 −0.14131 cg11462252 SLIT3 215511 −0.14143 cg02711975 SNTG2 55231 −0.14153 cg18890417 RHOBTB2; RHOBTB2; 342552 RHOBTB2 −0.14155 cg19704102 355015 −0.14158 cg01982724 40687 −0.14161 cg01506917 TRERF1 31222 −0.14162 cg13868106 256590 −0.14164 cg27121538 SV2B; SV2B 473253 −0.14179 cg18657389 EVPL 338738 −0.14191 cg07044115 137597 −0.14228 cg26775558 TCF7L2; TCF7L2; TCF7L2; 467042 TCF7L2; TCF7L2; TCF7L2 −0.14233 cg01860954 38147 −0.14249 cg23951190 CPNE4 421020 −0.14255 cg20721467 MYST4 371233 −0.14265 cg12138483 CLPP 227002 −0.14272 cg11478024 ANKS1A 215738 −0.14274 cg16289449 FERMT3; FERMT3; FERMT3; 299541 FERMT3 −0.14274 cg14050363 260484 −0.14285 cg03905247 NCOR2; NCOR2 78635 −0.14288 cg08993079 ADAM12; ADAM12 173319 −0.14309 cg16224727 FBRSL1 298403 −0.14309 cg06385449 FERMT3; FERMT3 124889 −0.1432 cg17594351 MYF6 321588 −0.14328 cg12464631 232068 −0.14333 cg04244932 85279 −0.14351 cg04955877 ZHX2 98883 −0.14362 cg07618453 KCNQ1; KCNQ1 148575 −0.14384 cg27121309 ACER3 473247 −0.14384 cg14807945 ZEB2; ZEB2 275475 −0.14392 cg04142988 PCSK6; PCSK6; PCSK6; PCSK6; 83265 PCSK6; PCSK6; PCSK6; PCSK6 −0.14429 cg00925950 PSKH1 19464 −0.14432 cg21933359 KHDRBS3 389559 −0.14433 cg11287400 MITF; MITF; MITF 212678 −0.14465 cg00926267 MKL1 19470 −0.14468 cg16098340 MIR548C; RASSF3 296333 −0.14478 cg08630040 166875 −0.14489 cg25880242 451900 −0.145 cg09706277 CD276; CD276 185655 −0.14524 cg07062388 LMBRD1 137963 −0.14533 cg02470874 PPM1L 50305 −0.14552 cg00997251 ARHGAP26; ARHGAP26 20995 −0.1456 cg16996242 ZMYM4 311738 −0.14564 cg12316142 DPYSL3 229823 −0.14568 cg05624853 HSD3B7; HSD3B7; HSD3B7 111349 −0.14588 cg05433460 ARHGAP1; ZNF408 108004 −0.1463 cg01226417 25743 −0.14632 cg00063979 1516 −0.14661 cg00498804 ST5; ST5; ST5 10580 −0.14682 cg22132509 PPM1L 392374 −0.14711 cg22166248 NXPH2 392926 −0.14724 cg02563600 KIAA0182; KIAA0182 52166 −0.14756 cg12681001 TNF 235670 −0.14759 cg23590159 UBXN11; UBXN11; UBXN11 415243 −0.14761 cg21528927 SLC6A12; SLC6A12; SLC6A12 383331 −0.1477 cg02742775 C12orf34 55869 −0.14778 cg10273072 C21orf34 195585 −0.14801 cg22927076 404363 −0.14817 cg03070550 HTRA1 62547 −0.14858 cg18791929 MYH15 340884 −0.14861 cg05991539 C6orf25; C6orf25; C6orf25; 118154 C6orf25; C6orf25; C6orf25 −0.14869 cg02092181 DOT1L 42966 −0.1488 cg13798679 255238 −0.14883 cg17073306 MYL5; MYL5 312976 −0.1489 cg17015179 PPT1; PPT1 312048 −0.14935 cg01343936 27981 −0.14948 cg11258484 212233 −0.14951 cg13971140 LASS4 258695 −0.14961 cg07282201 TBC1D10C 142343 −0.14982 cg12424504 MACC1 231361 −0.14985 cg01312762 CCDC134 27446 −0.15027 cg09568355 183338 −0.15031 cg08800856 NRXN2; NRXN2 169806 −0.15034 cg23617530 415668 −0.15048 cg02076598 KIAA1671 42633 −0.15058 cg18375707 PLCB3 334103 −0.1507 cg15833565 ERI3 291986 −0.15079 cg04101009 82356 −0.15089 cg09302355 FERMT3; FERMT3 178600 −0.15093 cg06191091 121594 −0.1512 cg07812957 152057 −0.15121 cg11724147 HIBADH 219728 −0.15134 cg27402999 SLC9A9 477987 −0.15154 cg02814691 NPL 57253 −0.15199 cg03907570 PRKAR1B; PRKAR1B; 78679 PRKAR1B; PRKAR1B; PRKAR1B; PRKAR1B −0.15217 cg13166875 SEC14L3 242924 −0.15227 cg26048923 TRAPPC9; TRAPPC9 454532 −0.15243 cg12884495 WBP2; UNC13D 238717 −0.15272 cg23558764 414863 −0.15282 cg05648614 ARL8B 111782 −0.15283 cg07449758 C6orf25; C6orf25; C6orf25; 145282 C6orf25; C6orf25; C6orf25 −0.15287 cg19642408 354063 −0.15303 cg14831085 PCSK6; PCSK6; PCSK6; PCSK6; 275823 PCSK6; PCSK6; PCSK6; PCSK6 −0.15304 cg01882991 38611 −0.15305 cg20848130 GJC2 373060 −0.15327 cg16032111 PPP2R1B; PPP2R1B 295322 −0.15331 cg12268531 HSP90B3P 229089 −0.15337 cg08287887 OR7E37P 160856 −0.15355 cg14526997 EHMT1; EHMT1 270270 −0.15364 cg06569229 FAT3 128143 −0.15382 cg26485376 462139 −0.15389 cg15513221 286669 −0.15389 cg08577912 165952 −0.15392 cg05778820 SLC9A1 114033 −0.15397 cg02222066 CYTH1; CYTH1 45356 −0.15413 cg02112681 C7orf50; C7orf50; C7orf50 43376 −0.15419 cg02913511 CNNM4 59256 −0.15421 cg25368116 444093 −0.15435 cg01357135 PPM1L 28229 −0.15439 cg26139338 KLF12 456089 −0.15451 cg19351617 SIGIRR; SIGIRR; SIGIRR 349235 −0.15453 cg22852065 SPATA18 403114 −0.15478 cg14455925 268761 −0.15478 cg00594561 DLX3 12719 −0.15482 cg26114961 C6orf25; C6orf25; C6orf25; 455644 C6orf25; C6orf25; C6orf25 −0.15511 cg09996076 HSD3B7; HSD3B7; HSD3B7; 190546 SETD1A −0.15544 cg07821417 ARVCF 152230 −0.1557 cg23991482 LSM7 421773 −0.15611 cg00751386 CTNNA2; CTNNA2 15883 −0.15614 cg02316852 RPA1 47305 −0.15619 cg21350115 CALCRL; CALCRL 380795 −0.15672 cg12526091 233088 −0.1568 cg02481950 METTL9; IGSF6; METTL9 50548 −0.157 cg19019345 ST5 344432 −0.15712 cg13552337 NDOR1; NDOR1; NDOR1; 250119 NDOR1 −0.15733 cg19321263 TRIM26 348840 −0.15767 cg07506749 146418 −0.15773 cg26197679 457116 −0.15792 cg03680790 STX2; STX2 74392 −0.15802 cg05744888 EIF2C2; EIF2C2 113460 −0.1583 cg00433709 ZNRF1 9174 −0.15835 cg22856279 403194 −0.15845 cg15256491 FOXK1 282829 −0.15854 cg20171297 MYF6; MYF6 362835 −0.15858 cg11244402 FOXO1 211986 −0.15879 cg14510322 269863 −0.15902 cg24236839 KDM4B 425869 −0.15907 cg01353907 GPR133 28172 −0.15926 cg23935522 ZDHHC17 420759 −0.15938 cg01893068 38791 −0.15944 cg20432350 KCND3; KCND3 366636 −0.15948 cg07453773 ST5; ST5; ST5 145358 −0.15956 cg11370814 214057 −0.15957 cg07820423 152210 −0.15972 cg00550928 MGAT3; MGAT3 11698 −0.15977 cg16576811 NEDD4L; NEDD4L; NEDD4L; 304754 NEDD4L; NEDD4L; NEDD4L; NEDD4L; NEDD4L; NEDD4L −0.15996 cg03285617 NT5E 66533 −0.1605 cg08145262 FRS2; FRS2 158124 −0.16083 cg07791897 151636 −0.16096 cg13127591 KRTAP9-9; KRTAP9-8 242341 −0.1612 cg00029979 743 −0.1613 cg18702278 PDE6B; PDE6B; PDE6B 339372 −0.16132 cg25683744 NINJ2 449043 −0.16135 cg13675051 RNF19A; RNF19A 252709 −0.16155 cg20364025 GALNS 365624 −0.16174 cg22649800 OGDH; OGDH 399813 −0.16179 cg07692929 OLFML1 149840 −0.16208 cg02903929 59057 −0.16229 cg10447977 ADAMTS9 198519 −0.1623 cg05383524 MGRN1; MGRN1; MGRN1; 107108 MGRN1 −0.16237 cg25902666 CSNK1G2 452187 −0.16237 cg07662964 BRD1; LOC90834 149327 −0.16243 cg14299931 ARHGEF7; ARHGEF7; 265726 ARHGEF7; ARHGEF7; ARHGEF7; ARHGEF7 −0.16257 cg02017814 NSMCE2 41390 −0.16265 cg01703196 34921 −0.16293 cg02119955 ITGBL1 43511 −0.16305 cg17987982 327555 −0.1631 cg02449461 ARRB1; ARRB1 49866 −0.16315 cg03928874 LY86 79027 −0.16339 cg07735586 150671 −0.1634 cg21089930 DTX4 376611 −0.16371 cg25105578 440013 −0.16389 cg04021454 TAF12; TAF12 80874 −0.16408 cg21126020 TRIM10; TRIM10 377162 −0.16417 cg27395226 SRPK2 477869 −0.16428 cg09141623 PRKG1; PRKG1 175757 −0.16437 cg16746362 C6orf25; C6orf25; C6orf25; 307984 C6orf25; C6orf25; C6orf25 −0.16464 cg03273420 SMCR7; SMCR7; SMCR7 66322 −0.16496 cg04221461 AKT3; AKT3 84805 −0.16524 cg13573761 C4orf23 250625 −0.1653 cg17807913 324584 −0.16531 cg19506253 CYTIP 351732 −0.16538 cg00895231 18812 −0.16547 cg00671823 GTF3C1 14204 −0.16584 cg23632029 OR10A5 415943 −0.16593 cg04345118 PAX8; PAX8; LOC654433; 87257 PAX8; PAX8; PAX8; LOC440839 −0.16595 cg09228831 GPRIN3 177227 −0.16609 cg05910124 TRAPPC9; TRAPPC9 116485 −0.16622 cg15124432 CDC34 280793 −0.16631 cg03199366 64930 −0.16651 cg21524538 SDCBP2 383268 −0.16652 cg22950982 MAPKAPK3 404771 −0.1666 cg26807536 LOC100271831; GDPD3 467662 −0.16661 cg16618389 305550 −0.16665 cg18347607 333691 −0.16674 cg24828746 ZBTB7A 435490 −0.16708 cg01386735 LMBRD1 28819 −0.16723 cg12214366 ANTXR2; ANTXR2 228267 −0.16727 cg04132452 PPM1L 83027 −0.1674 cg17923377 BRD1; LOC90834 326503 −0.1675 cg00659931 PCSK6; PCSK6; PCSK6; PCSK6; 13955 PCSK6; PCSK6; PCSK6; PCSK6 −0.16751 cg01412400 RPTOR; RPTOR 29361 −0.16763 cg18507146 ZNF236 336390 −0.16773 cg17001765 PGBD2; PGBD2 311841 −0.16781 cg23683146 416923 −0.16815 cg22688687 C19orf42 400457 −0.16825 cg10969245 DAGLA 207350 −0.16826 cg15637527 ARHGAP1 288736 −0.16829 cg11903920 TCERG1L 223003 −0.1685 cg15268191 283001 −0.16862 cg03204322 SAMD13; SAMD13; SAMD13 65015 −0.16866 cg09906928 LHFPL2 189108 −0.1688 cg23808165 418718 −0.16903 cg15594550 ZNF696 287945 −0.16921 cg08462367 163870 −0.16922 cg07412186 ATXN1; ATXN1 144647 −0.16923 cg02988730 AMPD2; AMPD2; AMPD2 60882 −0.16929 cg20090290 AMBRA1 361565 −0.16937 cg25296103 ZEB2; ZEB2 442878 −0.1694 cg25124489 PRKCE 440332 −0.1695 cg07739478 C6orf25; C6orf25; C6orf25; 150742 C6orf25; C6orf25; C6orf25 −0.16956 cg10090414 192177 −0.16978 cg08937102 NADK 172382 −0.16999 cg10785394 204327 −0.17008 cg05425699 TNS3 107909 −0.1701 cg12987138 240257 −0.17028 cg04558553 UGT2B7 91298 −0.17028 cg21764632 WIPI2; WIPI2; WIPI2; WIPI2; 386908 WIPI2 −0.17032 cg01306151 C16orf7 27295 −0.17039 cg22718891 400997 −0.17042 cg21346154 TGFA; TGFA 380741 −0.17048 cg21241151 379374 −0.17049 cg25091527 COL4A1 439775 −0.17072 cg26581714 SPATA18 463898 −0.17077 cg04771838 COL4A2 95213 −0.17083 cg04988694 TBCD 99510 −0.17083 cg05697734 112662 −0.17096 cg25221919 441857 −0.17096 cg18071202 LOC100292680 328953 −0.17113 cg19184688 346756 −0.17114 cg13740185 C10orf105; CDH23 254087 −0.17123 cg05801329 114496 −0.17126 cg26576576 PTPN14 463811 −0.17157 cg14692453 ANKRD23 273553 −0.17158 cg10143416 193223 −0.17163 cg05856321 115416 −0.17167 cg00230120 LOC100292680 4919 −0.17176 cg24152251 424608 −0.17178 cg18030453 LARS2 328261 −0.17206 cg25749107 450067 −0.17211 cg26457569 KANK2; KANK2 461638 −0.17223 cg08890627 SEC14L1; SEC14L1; SEC14L1; 171586 SEC14L1; SEC14L1 −0.17237 cg22481643 C3orf26; FILIP1L; MIR548G; 397283 FILIP1L; FILIP1L −0.17247 cg08791347 FRMD4A 169648 −0.17248 cg08656333 167353 −0.17277 cg14121740 261943 −0.17277 cg05514531 GBE1 109409 −0.17287 cg00045902 PWWP2B; PWWP2B 1131 −0.17294 cg20584712 BAT2 368914 −0.17333 cg09305096 GULP1 178661 −0.17333 cg09156542 176059 −0.17338 cg05660874 SPPL2B; SPPL2B 112045 −0.17344 cg01397912 C19orf51; TNNI3 29052 −0.17357 cg19164997 CAPN5 346507 −0.17408 cg26110562 AGAP1; AGAP1 455549 −0.17424 cg19583934 RASA3 352999 −0.17429 cg20319604 PPM1B; PPM1B; PPM1B; 364994 PPM1B; PPM1B −0.17454 cg02955940 CORIN 60186 −0.17456 cg05426956 HTRA1 107922 −0.17468 cg00128100 KIAA1949; NRM; KIAA1949 2929 −0.17519 cg01786151 36566 −0.17536 cg20788482 372245 −0.17539 cg04724873 KIAA1751 94344 −0.17547 cg11473240 KRT31 215681 −0.17547 cg10539122 NAV1; MIR1231; NAV1 200240 −0.17549 cg02123534 ADAP1 43564 −0.17597 cg05776861 ARHGEF7; ARHGEF7; 113995 ARHGEF7; ARHGEF7; ARHGEF7 −0.17599 cg01104590 CARS; CARS; CARS; CARS 23322 −0.17623 cg24888581 AGAP1; AGAP1 436607 −0.17625 cg18805457 TCERG1; TCERG1 341130 −0.17669 cg08189139 158940 −0.17672 cg17644903 ZDBF2 322224 −0.17677 cg20725334 371301 −0.1769 cg00851627 17937 −0.177 cg05891054 STAT5B 116105 −0.17702 cg13609694 251374 −0.17731 cg19482843 EIF2C2; EIF2C2 351362 −0.17753 cg19975759 B3GNTL1 359813 −0.17754 cg24864413 SLC22A1; SLC22A1 436118 −0.1776 cg10592521 MEX3D 201161 −0.17783 cg21548131 NLGN1 383703 −0.178 cg02971328 RAC1; RAC1 60519 −0.17804 cg04857881 ITFG1 96921 −0.17826 cg16653138 PRKCZ; PRKCZ; PRKCZ 306192 −0.17831 cg22146612 392580 −0.17849 cg17627813 PRDM10; PRDM10; PRDM10; 322003 PRDM10 −0.17863 cg24522085 LASS6 430348 −0.17898 cg02374207 MACROD1 48511 −0.17927 cg01286133 APP; APP; APP; APP; APP 26850 −0.17931 cg04644504 SENP8; MYO9A 92888 −0.17974 cg01923312 SLC22A3 39391 −0.1805 cg25541708 446789 −0.1806 cg15852553 292348 −0.18062 cg18722504 HBEGF 339716 −0.18072 cg20440552 366770 −0.18085 cg12979590 CUGBP1 240142 −0.18112 cg18664915 C7orf50; C7orf50; C7orf50 338829 −0.18131 cg18080303 LAMA4; LAMA4; LAMA4; 329086 LAMA4; LAMA4 −0.18135 cg12496975 RAPGEF3; RAPGEF3; RAPGEF3 232622 −0.18167 cg25677376 448951 −0.18198 cg06476926 TBCD 126410 −0.18258 cg16161418 KIAA1949; KIAA1949 297331 −0.18265 cg14661139 UBE2J2; UBE2J2; 273045 LOC100128842; UBE2J2; UBE2J2 −0.18273 cg07930874 SLAIN1; SLAIN1 154214 −0.18302 cg13912858 SORT1 257507 −0.18327 cg06059810 RUFY3; RUFY3; RUFY3; 119317 RUFY3; RUFY3 −0.18359 cg01822532 LRP5 37414 −0.18366 cg05059607 PITPNC1; PITPNC1 100893 −0.18367 cg07547798 NSMCE2 147165 −0.18371 cg04761972 95031 −0.18382 cg15932980 STX2; STX2 293635 −0.18394 cg17425351 318837 −0.18398 cg09777237 ELN; ELN; ELN; ELN; ELN 186754 −0.18403 cg04068914 MTHFSD; MTHFSD; MTHFSD; 81718 MTHFSD; MTHFSD; MTHFSD; MTHFSD; FLJ30679 −0.18411 cg07224918 ARHGEF10L; ARHGEF10L 141354 −0.1845 cg24269082 TBCD 426275 −0.18457 cg00646241 SHANK2 13697 −0.18467 cg24290996 426537 −0.18474 cg13690679 253081 −0.18479 cg18926409 343073 −0.18495 cg19589494 353114 −0.18496 cg12806353 PLA1A 237540 −0.1853 cg00237010 NINJ2 5072 −0.18559 cg04144521 MFSD6 83296 −0.18565 cg07833951 152463 −0.18583 cg04056576 PPM1L 81465 −0.18583 cg14837896 THBS4 275954 −0.18588 cg22330533 BRD1; LOC90834 395190 −0.18592 cg03659680 LYN; LYN 73997 −0.18618 cg06795960 ARL4D 132561 −0.1862 cg14679230 LIPE 273341 −0.18622 cg00873517 KHDRBS3 18398 −0.18626 cg13613044 251444 −0.18636 cg20021790 RPH3AL 360547 −0.1866 cg08279097 DCLRE1B 160695 −0.18672 cg13613439 PHYHD1; PHYHD1; PHYHD1; 251453 PHYHD1; PHYHD1 −0.18676 cg25331919 LIPG 443459 −0.18684 cg16046833 SNX7; SNX7 295544 −0.18685 cg02535674 51638 −0.18728 cg27554156 GSG1; GSG1; GSG1; GSG1 480508 −0.18728 cg24940885 437453 −0.1873 cg02360002 48201 −0.18738 cg04912273 SLC9A1 98039 −0.18751 cg18321354 CARD11 333265 −0.18756 cg10453419 PCSK6; PCSK6; PCSK6; PCSK6; 198614 PCSK6; PCSK6; PCSK6; PCSK6 −0.18757 cg04833731 GDPD3; GDPD3; LOC100271831 96391 −0.18789 cg16872841 COL4A2 309904 −0.18796 cg08176694 PITPNM2 158725 −0.1881 cg08426898 163219 −0.18822 cg02813863 APOLD1; APOLD1 57236 −0.1885 cg02959282 NCK1 60268 −0.1885 cg11458974 HMOX1 215460 −0.18885 cg01156373 ERBB4; ERBB4 24354 −0.18902 cg08405910 NCK2; NCK2; NCK2 162877 −0.18904 cg06445944 PIK3R1; PIK3R1; PIK3R1 125887 −0.18909 cg19623595 353718 −0.18909 cg05145297 HIP1 102438 −0.18938 cg11626175 JARID2 218013 −0.18939 cg05310046 THSD4 105621 −0.18981 cg26005086 JAG1 453833 −0.18991 cg09990852 RUFY3; RUFY3; RUFY3; 190465 RUFY3; RUFY3 −0.19005 cg23413567 FOXO1 412578 −0.19014 cg11815008 CETN1 221367 −0.19024 cg14883993 NFIC; NFIC 276772 −0.1905 cg27302175 ZSWIM6 476195 −0.19064 cg05647929 CFC1B; CFC1 111770 −0.19077 cg00859622 VSTM2L 18096 −0.19081 cg25940447 GNPDA1 452774 −0.19085 cg00213052 4580 −0.19087 cg03057216 VPS72; TMOD4 62283 −0.19087 cg01932663 C3orf26; FILIP1L; FILIP1L 39583 −0.19118 cg25026329 APLP2; APLP2; APLP2; APLP2; 438829 APLP2; APLP2 −0.1912 cg06758827 TRIO 131795 −0.19133 cg09353563 UACA; UACA; UACA 179511 −0.19136 cg20629021 CPT1A; CPT1A 369542 −0.19145 cg07823562 CYTH1; CYTH1 152263 −0.19146 cg23429240 CORO1C 412803 −0.19147 cg03320743 67233 −0.19215 cg10407488 ARHGEF12 197843 −0.19222 cg19876649 MYOM1; MYOM1 358154 −0.19233 cg13148151 LIMD1 242630 −0.19234 cg24073770 423219 −0.19257 cg08010094 NXPH2 155586 −0.19262 cg01742357 RAPGEF4; RAPGEF4 35676 −0.19263 cg05957190 CHST11 117447 −0.19286 cg07394266 C9orf71 144374 −0.19326 cg00689612 TIMP2 14559 −0.19327 cg12131324 RPTOR; RPTOR 226898 −0.19329 cg07155381 RPH3AL 139908 −0.1934 cg13189271 JARID2 243319 −0.19379 cg03447908 CLEC3B 69735 −0.1938 cg19185706 LDB3; LDB3; LDB3 346776 −0.19452 cg12744888 MYH15 236621 −0.19464 cg04081835 81973 −0.1948 cg05297666 ETS1 105349 −0.19506 cg19252218 ARL4D 347770 −0.19508 cg11668573 FNIP2 218773 −0.19509 cg07879785 CRYL1 153222 −0.19518 cg04005958 80561 −0.19522 cg01617074 SLC45A4; SLC45A4 33454 −0.19532 cg12560421 233610 −0.19534 cg00498089 10560 −0.19543 cg17622952 321946 −0.1955 cg05541460 109873 −0.19558 cg02073224 MEGF6 42570 −0.19569 cg07983363 PCSK6; PCSK6; PCSK6; PCSK6; 155143 PCSK6; PCSK6; PCSK6; PCSK6 −0.19582 cg00989315 CDCA7L; CDCA7L; CDCA7L 20808 −0.19585 cg11634496 218142 −0.19592 cg14887955 276836 −0.19603 cg10345724 C7orf50; C7orf50; C7orf50 196843 −0.1963 cg14002578 GALNT12 259402 −0.19635 cg02670123 ITGA6; ITGA6 54419 −0.19673 cg12056017 ANKRD44 225506 −0.19679 cg03462604 C2orf18 70013 −0.1968 cg02800733 CD320; CD320 57003 −0.19696 cg18835549 TRIM40 341642 −0.19701 cg08079387 LOC90834; BRD1 156793 −0.19706 cg22251117 RPH3AL 394137 −0.19709 cg02382878 48672 −0.1974 cg14710529 ASAP2; ASAP2 273872 −0.19767 cg01891925 BTC 38772 −0.19768 cg20439101 MAP3K1 366753 −0.19769 cg06709178 INPP5B 130792 −0.19814 cg07573020 ANKH 147681 −0.19821 cg08373573 MUC6 162363 −0.19832 cg27396760 CMIP; CMIP 477898 −0.19891 cg05796178 LZTS1 114384 −0.19909 cg25345520 443680 −0.19912 cg21562035 KANK2; KANK2 383932 −0.19945 cg06136573 120675 −0.19954 cg18756557 LOC100292680 340244 −0.19966 cg06049177 GSR 119151 −0.19972 cg24536145 SORBS2 430636 −0.19978 cg16875057 STK39 309942 −0.20006 cg01698392 TIMP2 34835 −0.2003 cg12251803 LRRFIP1; LRRFIP1; LRRFIP1; 228847 LRRFIP1; LRRFIP1 −0.20035 cg21007971 PLA2G6; BAIAP2L2; PLA2G6 375427 −0.20045 cg04142824 ATP11A; ATP11A 83262 −0.20048 cg00435616 C7orf50; C7orf50; C7orf50 9208 −0.20064 cg04094923 82221 −0.20076 cg13496793 ZBTB34 249014 −0.20101 cg23659250 BRD1; LOC90834 416462 −0.20138 cg15690822 RFFL; RFFL 289648 −0.2019 cg02019508 ATF7; ATF7; ATF7 41425 −0.20196 cg08577298 165938 −0.20213 cg25238480 GALNTL4 442087 −0.20221 cg12294678 NOS3 229476 −0.20232 cg21881338 AACS 388735 −0.2025 cg24901662 PARD3 436800 −0.20251 cg11407540 EGF 214668 −0.20269 cg07069839 138124 −0.20308 cg21931263 389515 −0.20316 cg11561301 C4orf6 216983 −0.20337 cg07795513 ATF6 151706 −0.20362 cg04589673 91937 −0.20374 cg06418113 RNF165 125411 −0.20385 cg01471802 TRIM6- 30616 TRIM34; TRIM6; TRIM6 −0.20416 cg15884713 NINJ2 292821 −0.2046 cg22043118 TMED7- 391069 TICAM2; TICAM2; TMED7- TICAM2 −0.20502 cg07593326 PCCA; PCCA 148106 −0.20504 cg12800012 SH3PXD2A 237419 −0.20507 cg04667640 ZFHX3; ZFHX3 93314 −0.20511 cg00527307 11212 −0.2055 cg13300630 ROBO1; ROBO1; ROBO1; 245107 ROBO1 −0.20558 cg25888386 452027 −0.2057 cg03571277 ACCN1 72232 −0.20574 cg19660729 KIF26A 354335 −0.206 cg13689563 ZNF136 253055 −0.20627 cg27585074 CSNK1G2 481080 −0.20638 cg25266816 442457 −0.20669 cg15984712 294427 −0.2068 cg08124461 CGNL1 157691 −0.20692 cg12555652 ITGBL1 233545 −0.20701 cg06707286 PCSK6; PCSK6; PCSK6; PCSK6; 130749 PCSK6; PCSK6; PCSK6; PCSK6 −0.20713 cg12758625 RNF24; RNF24; RNF24 236809 −0.20719 cg16241878 FRMD5 298677 −0.20733 cg06389019 SLC9A3R1 124935 −0.20737 cg02803847 BUB3; BUB3 57065 −0.20737 cg07376547 144035 −0.20746 cg20625588 MUC6 369496 −0.20756 cg05415840 ARC; ARC 107735 −0.2077 cg00311751 TRERF1 6568 −0.20775 cg02465887 DCHS2 50200 −0.20799 cg02392737 ADCY9 48895 −0.20804 cg13043815 C21orf63 241083 −0.20812 cg06232466 CACNA1H; CACNA1H 122343 −0.20827 cg08490246 164404 −0.20838 cg05964487 117593 −0.20854 cg15891850 KLF12 292938 −0.20874 cg20218678 FAM10A4 363445 −0.20882 cg01569709 32505 −0.20902 cg15044010 SRPK2; SRPK2 279419 −0.20915 cg10269431 EGF 195527 −0.20964 cg01064758 TG; SLA; SLA 22444 −0.21022 cg12597325 STX2; STX2 234249 −0.21045 cg20263733 ATP2C1; ATP2C1; ATP2C1; 364115 ATP2C1 −0.21084 cg02872914 CTBP2; CTBP2; CTBP2 58381 −0.21116 cg14153069 PHYHD1; PHYHD1; PHYHD1; 262529 PHYHD1; PHYHD1 −0.21127 cg21617357 HTATIP2; HTATIP2; HTATIP2; 384851 HTATIP2; HTATIP2 −0.2114 cg23723013 KCNAB1; KCNAB1; KCNAB1 417619 −0.21172 cg02497428 METTL9; IGSF6; METTL9 50892 −0.2118 cg12018521 TES 224833 −0.21202 cg02773403 ANK3 56524 −0.21204 cg00765737 COL4A2 16178 −0.21216 cg06432487 125644 −0.21225 cg13447820 247908 −0.21276 cg04470324 FSTL4 89614 −0.21292 cg26295272 FLNB; FLNB; FLNB; FLNB 458803 −0.21314 cg05450916 TGFBR2; TGFBR2 108229 −0.21317 cg04893454 97666 −0.21341 cg22219255 393632 −0.21349 cg23198558 ARHGAP26; ARHGAP26 408866 −0.21367 cg19353947 ZEB2; ZEB2; ZEB2 349264 −0.21373 cg04208996 84534 −0.2138 cg02534659 51624 −0.21385 cg04266607 JAZF1 85718 −0.21392 cg07042532 CREB5; CREB5; CREB5 137576 −0.21393 cg09130535 ADRBK1 175551 −0.21397 cg24919468 437059 −0.21428 cg00058644 1391 −0.2144 cg06127541 RRAS2; RRAS2 120526 −0.21446 cg16497661 CKB 303238 −0.21492 cg02712587 EIF2AK4 55252 −0.21494 cg00232092 FBXL18 4975 −0.21509 cg13679772 FOXN3 252820 −0.21555 cg01915822 ADCK5 39234 −0.21558 cg11460562 TNPO1; TNPO1 215482 −0.21561 cg14375985 CTBP2; CTBP2; CTBP2 267187 −0.21562 cg04267284 PYGB 85734 −0.21585 cg19093405 CACNA2D3 345515 −0.21621 cg02668218 54387 −0.21671 cg25286715 442752 −0.21697 cg14772660 SLC5A7 274806 −0.21707 cg01495332 GRB10; GRB10; GRB10 31016 −0.21758 cg00446697 HCCA2 9405 −0.21821 cg03844838 DIP2C 77475 −0.21834 cg25799348 FOXK1 450816 −0.21849 cg08702689 PRRX1; PRRX1 168159 −0.21863 cg13495373 CREB5; CREB5; CREB5 248982 −0.21887 cg11165960 210588 −0.21906 cg24721647 ACSL1 433758 −0.21922 cg15380511 284521 −0.21944 cg07739826 OSBP 150749 −0.21962 cg18780243 EEF1DP3 340687 −0.21966 cg13289202 ABTB2 244906 −0.21972 cg00684423 GPER; C7orf50; C7orf50; GPER; 14439 C7orf50 −0.21994 cg06013113 RAB40C 118547 −0.21999 cg18129282 330053 −0.22012 cg26325949 SYNPO2; SYNPO2; SYNPO2 459352 −0.22027 cg07091154 SHANK2 138518 −0.22031 cg27584112 481064 −0.22034 cg20203400 TMEM182 363230 −0.22065 cg14125542 FAM49A 262013 −0.22071 cg00380924 RPS6KA2; RPS6KA2 8060 −0.22081 cg18887296 PPFIA3 342507 −0.22107 cg17858500 C20orf27 325500 −0.22142 cg04974647 99207 −0.22165 cg20334115 PYCR2 365215 −0.22175 cg16523645 ITPK1; ITPK1; ITPK1 303721 −0.22212 cg12525096 233069 −0.22213 cg20131219 PHLDB2; PHLDB2; PHLDB2; 362199 PHLDB2 −0.22244 cg21750426 MIRLET7C; C21orf34; C21orf34; 386667 MIR99A −0.22263 cg17918796 326430 −0.22269 cg14165772 262803 −0.22294 cg14081251 ST6GALNAC4; ST6GALNAC4 261114 −0.22318 cg01824625 EPHA3; EPHA3 37465 −0.22327 cg20080845 BRD1; LOC90834 361454 −0.2235 cg15016481 LRRFIP1; LRRFIP1; LRRFIP1; 278955 LRRFIP1; LRRFIP1 −0.22429 cg04112058 SHCBP1 82595 −0.22434 cg17879450 MACF1 325874 −0.2244 cg12399224 ZBTB46 230928 −0.22443 cg22909677 ARMC2 404123 −0.22448 cg25874123 MYOM1; MYOM1 451828 −0.22451 cg18720326 ADAMTS2; ADAMTS2 339675 −0.2246 cg16230121 APBB1; APBB1 298473 −0.22463 cg21848191 RAD51L1; RAD51L1; RAD51L1 388170 −0.22463 cg19026231 GALK1 344545 −0.22483 cg07080231 138324 −0.22528 cg17531430 BIN1; BIN1; BIN1; BIN1; BIN1; 320696 BIN1; BIN1; BIN1; BIN1; BIN1 −0.22531 cg07807373 151942 −0.22568 cg09038971 CHST11 174071 −0.22576 cg16624521 305662 −0.22583 cg10031769 CREM; CREM; CREM; CREM; 191189 CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM; CREM −0.22674 cg15853771 292370 −0.22677 cg05242915 104329 −0.22727 cg09264140 FMNL1 177950 −0.22741 cg24977338 RGPD8; RGPD5 437964 −0.22749 cg27469810 CETN1 479043 −0.22788 cg00653025 13831 −0.22788 cg05285759 TBCK; TBCK; TBCK; TBCK 105125 −0.22818 cg12642431 UACA; UACA 235055 −0.22826 cg09169413 P11 176276 −0.22856 cg23079012 407020 −0.2289 cg23904501 PTPRS; PTPRS; PTPRS; PTPRS 420216 −0.22901 cg07631435 ZBTB16; ZBTB16 148813 −0.22976 cg13752933 DAPK1 254331 −0.22984 cg19173502 MIRLET7C; C21orf34; C21orf34 346603 −0.22995 cg21502482 SPATA7; SPATA7 382912 −0.22997 cg03144446 63874 −0.23001 cg01164141 24508 −0.23003 cg27314273 PTPRG 476489 −0.23018 cg13879937 EHD4 256817 −0.23035 cg11168687 ACSL1 210627 −0.23037 cg22905866 404070 −0.23047 cg19788250 APP; APP; APP; APP; APP 356630 −0.23055 cg19478371 PPP2R5C; PPP2R5C; PPP2R5C; 351294 PPP2R5C; PPP2R5C −0.23081 cg08153404 158265 −0.23098 cg11945474 223676 −0.23103 cg07470830 145712 −0.23116 cg09537792 ANKRD11 182760 −0.23122 cg17880118 COL4A1 325886 −0.2315 cg07468585 145653 −0.23177 cg00108038 LOC100292680 2509 −0.23183 cg23560676 NSMCE2 414881 −0.23213 cg11063877 LARP4; LARP4; LARP4; LARP4; 208898 LARP4; LARP4; LARP4 −0.23228 cg19735406 COL4A2 355626 −0.23258 cg09259797 177870 −0.23286 cg05314142 SLC22A1; SLC22A1 105694 −0.23299 cg06519061 PTPN14 127144 −0.23315 cg26983411 470886 −0.23331 cg01417625 LAMC2; LAMC2 29483 −0.23345 cg06112923 STEAP2; STEAP2; STEAP2 120290 −0.23386 cg22416916 SLC22A1; SLC22A1 396454 −0.23403 cg10492417 FANCA 199244 −0.23409 cg02540833 SHANK2 51760 −0.2342 cg09329079 TMEM184A 179139 −0.23446 cg08135718 CUX1; CUX1; CUX1 157939 −0.23468 cg20724690 CAB39; CAB39; CAB39 371287 −0.23494 cg20192387 RPS6KA2; RPS6KA2 363087 −0.23519 cg09169739 GFPT2 176289 −0.23558 cg22396663 MAD1L1; MAD1L1; MAD1L1 396208 −0.23597 cg02923628 59493 −0.23632 cg03109660 RELL1; RELL1 63223 −0.23648 cg06562964 RELL1; RELL1 128035 −0.23857 cg17133045 AKT3; AKT3 313972 −0.23937 cg03606098 NADK 72963 −0.23938 cg18771195 RPH3AL 340542 −0.23963 cg10013121 TRERF1 190859 −0.23979 cg02781060 56673 −0.23996 cg22117968 392140 −0.2401 cg11520719 ARID1B; ARID1B; ARID1B 216320 −0.24011 cg04126956 TRAPPC9; TRAPPC9 82912 −0.24087 cg01312265 TCERG1L 27436 −0.24102 cg09873409 PLXNA4; PLXNA4 188543 −0.24159 cg00089451 2073 −0.24161 cg27446233 PFKM; PFKM; PFKM; PFKM; 478685 PFKM −0.24161 cg07251141 ADAM12; ADAM12 141811 −0.24173 cg02773698 FCHSD2 56533 −0.2419 cg11028872 208387 −0.24214 cg06865642 BRD1; LOC90834 134034 −0.24269 cg18000216 ERC2 327710 −0.24279 cg14558716 ATF1 270966 −0.24303 cg06165742 FOXP2; FOXP2; FOXP2 121155 −0.24317 cg07491828 MKL2 146139 −0.24321 cg05495611 EXT2; EXT2 109044 −0.24432 cg00264129 HBEGF 5659 −0.24487 cg20539449 368227 −0.24494 cg07877629 153192 −0.24502 cg00026412 ANK3 645 −0.24505 cg25089903 NINJ2 439753 −0.24567 cg23708624 CCDC146; FGL2 417387 −0.24585 cg25838968 PLXNA2 451397 −0.24656 cg02724461 GALNS 55487 −0.24687 cg23669855 LYSMD4 416659 −0.24737 cg19547694 BRD1; LOC90834 352451 −0.24757 cg13962170 258544 −0.24861 cg17798857 UACA; UACA 324425 −0.24871 cg09741789 FBN1 186193 −0.24879 cg04721825 PRKCA 94264 −0.24908 cg01556677 SEMA3C 32186 −0.24945 cg19450056 350853 −0.24949 cg25141441 RORA; RORA; RORA; RORA 440625 −0.24973 cg04265492 BAI2 85697 −0.2506 cg03870329 77949 −0.25077 cg25206802 SACS 441606 −0.25093 cg25483191 TRIM55; TRIM55; TRIM55; 445943 TRIM55 −0.25124 cg08535361 NTN4 165209 −0.25143 cg04425710 ESCO2; CCDC25 88827 −0.25168 cg08464954 163934 −0.25182 cg13661832 252443 −0.25199 cg10259111 GNG2 195382 −0.25214 cg24331722 427189 −0.25249 cg26529437 ITGB8 462893 −0.25283 cg25706447 PIGV 449350 −0.25296 cg26131670 SLC4A4; SLC4A4 455944 −0.25313 cg11274148 RPTOR; RPTOR 212468 −0.25324 cg14571004 GALNT12 271226 −0.25333 cg26306638 HBEGF 459010 −0.25362 cg08412699 ITGB8 162975 −0.25409 cg12208381 CSNK1G2 228165 −0.25453 cg11611676 217803 −0.25457 cg13665060 252509 −0.25472 cg16784943 ITPK1; ITPK1; ITPK1 308597 −0.25501 cg24534767 430608 −0.25576 cg03778207 ME3; ME3; ME3 76334 −0.25579 cg09088836 174888 −0.25665 cg26543192 463160 −0.2568 cg14457429 268785 −0.25731 cg16834726 DCTN2 309390 −0.25741 cg14523881 VASH2; VASH2; VASH2 270202 −0.25788 cg05208056 NCK2; NCK2; NCK2 103597 −0.25817 cg07525751 SLC6A3 146753 −0.25823 cg03855388 CPT1A; CPT1A 77697 −0.25832 cg22308453 DPYSL2 394900 −0.25865 cg07911905 CHST11 153817 −0.25865 cg05196076 FBXO31; FBXO31 103393 −0.25949 cg18371976 TRERF1 334048 −0.25957 cg16878214 PLEKHF2 309991 −0.25958 cg20655877 369984 −0.26099 cg21197233 ARHGAP20 378484 −0.26155 cg15568998 AGMAT 287517 −0.26178 cg27511861 479747 −0.26219 cg12564175 ESCO2; CCDC25 233667 −0.26237 cg16090790 296212 −0.2632 cg12552626 CCDC146; FGL2 233502 −0.26416 cg11072779 ANXA4 209068 −0.26569 cg22352504 HAS1 395515 −0.26608 cg07263759 142020 −0.26615 cg18022344 METTL9; IGSF6; METTL9 328111 −0.2662 cg24033633 422524 −0.26675 cg05310185 TACC2; TACC2; TACC2; TACC2 105623 −0.26683 cg02606505 NKTR 53079 −0.26684 cg05899338 ZNF239; ZNF239; ZNF239 116275 −0.26725 cg06385757 PRKAR1B; PRKAR1B; 124893 PRKAR1B; PRKAR1B; PRKAR1B; PRKAR1B −0.26763 cg14178899 ERRFI1 263095 −0.2679 cg03372385 LRRC16A 68299 −0.26797 cg25072766 CARS; CARS; CARS; CARS 439518 −0.26865 cg20608783 BAI2 369275 −0.26917 cg07776993 ADCK5 151365 −0.27071 cg01295631 27066 −0.27154 cg06836480 DHRS9; DHRS9; DHRS9 133449 −0.27159 cg01957599 FAM13AOS 40119 −0.2728 cg17478992 SLC12A8 319759 −0.27286 cg12884466 MRPL3 238716 −0.27379 cg13200640 243476 −0.27391 cg12619262 234658 −0.27459 cg26551026 CABLES1; CABLES1 463331 −0.27512 cg03078520 MICAL3; MICAL3; MICAL3 62698 −0.27559 cg19295451 PCSK6; PCSK6; PCSK6; PCSK6; 348451 PCSK6; PCSK6; PCSK6; PCSK6 −0.2759 cg01359165 28268 −0.27611 cg03389789 FBXW8; FBXW8 68597 −0.27642 cg27199697 DLX3 474550 −0.27828 cg19995595 ITPK1; ITPK1; ITPK1 360131 −0.2796 cg19600494 353349 −0.28011 cg22801134 PRICKLE2 402255 −0.28065 cg20140333 362329 −0.28088 cg00101350 MGAT3; MGAT3 2375 −0.28176 cg10784341 PHACTR2; PHACTR2 204295 −0.28206 cg23338380 CUX1; CUX1; CUX1 411370 −0.28216 cg22122925 ERRFI1 392216 −0.28241 cg06235645 SEMA6D; SEMA6D; SEMA6D; 122412 SEMA6D; SEMA6D; SEMA6D −0.28268 cg16474725 CLIC5; CLIC5 302879 −0.28421 cg14054582 260566 −0.2851 cg19926144 DIP2C 359006 −0.28525 cg26214026 ATXN2 457353 −0.28725 cg18030133 PHACTR2; PHACTR2; 328254 PHACTR2; PHACTR2 −0.28771 cg22716599 DNM3; DNM3 400952 −0.28822 cg00745735 MYPN 15768 −0.28884 cg02071553 MIR216B 42524 −0.28893 cg01756899 35949 −0.28929 cg05928904 116850 −0.28962 cg01598421 TG 33081 −0.28997 cg02131142 TBC1D9B; TBC1D9B 43723 −0.29156 cg03412557 RUNDC2A 69042 −0.29166 cg17947992 326928 −0.29212 cg00855685 SEMA5A 18020 −0.29231 cg08672203 PPAP2A; PPAP2A 167602 −0.29315 cg17613911 STK32A 321844 −0.29506 cg23666374 AUTS2; AUTS2; AUTS2 416583 −0.29533 cg16666745 GALNT10 306478 −0.2964 cg26826631 CD55; CD55 468043 −0.29748 cg17919396 ALDH1A3 326446 −0.29758 cg01574912 32628 −0.29814 cg14334389 SPARCL1; SPARCL1 266428 −0.29818 cg04304338 ANKRD33B 86451 −0.29932 cg02847703 BTC 57849 −0.30181 cg23155767 GPR1; GPR1 408172 −0.30344 cg09819635 KHDRBS3 187501 −0.30363 cg25131079 ADAMTS2; ADAMTS2 440427 −0.30642 cg12754854 PHYHD1; PHYHD1 236759 −0.30675 cg08943696 GPR133 172510 −0.30689 cg03983715 PRMT7 80095 −0.30824 cg09287328 178354 −0.30861 cg03713317 CYFIP1; CYFIP1 74995 −0.31349 cg23666829 TBCD 416590 −0.31884 cg26253868 458047 −0.32034 cg03700279 PREPL; PREPL; PREPL; PREPL; 74742 PREPL; PREPL; PREPL −0.32126 cg12894142 238844 −0.32278 cg16689609 UTRN 306875 −0.32343 cg12359895 LOC100216001; LOC338588 230357 −0.32409 cg19244380 AMBRA1; AMBRA1 347620 −0.32631 cg01928411 LARP4; LARP4; LARP4; LARP4; 39500 LARP4; LARP4; LARP4 −0.32706 cg25254949 442307 −0.32836 cg23159678 NOVA1; NOVA1; NOVA1 408237 −0.33031 cg11520439 LOC286367 216313 −0.33087 cg11937508 GPR1; GPR1 223523 −0.33212 cg12205433 TES; TES 228120 −0.33433 cg18901940 MYPN; MYPN 342719 −0.34043 cg10362527 GPR1; GPR1 197111 −0.34108 cg14570632 RXRA 271222 −0.34414 cg03361973 SEMA6D; SEMA6D; SEMA6D; 68105 SEMA6D; SEMA6D; SEMA6D −0.34417 cg05073720 PHLPP1 101171 −0.34459 cg16087541 TES; TES 296173 −0.34847 cg09835421 PRMT7 187811 −0.34934 cg21161187 SLC6A3 377787 −0.35195 cg02666566 54356 −0.35418 cg18262591 CPT1A; CPT1A 332336 −0.37588 cg16808481 TES; TES 309027 −0.38211 cg14604584 271938 −0.40768 cg05110241 PRMT7 101782 −0.41512 cg20071744 TRAPPC9; TRAPPC9 361314 −0.43386 cg15853299 TBCD 292363

TABLE 8 Associated OA − RA gene CpG* Locus SEQ ID No. −0.603 LIMS1 2: 109251064 cg10879348 205889 −0.603 15:97311928 cg04875706 97278 −0.572 17:35161825 cg11331837 213402 −0.563 ACOT11 1:55014160 cg01802772 36934 −0.552 GNAS 20:57463991 cg09885502 188727 −0.527 11:28642652 cg26387458 460494 −0.511 HDAC11 3:13555664 cg26845082 468403 −0.506 3:22422855 cg20979384 374956 −0.484 1:204556835 cg13232075 244024 −0.478 AP2A2 11:1001560 cg16999994 311801 −0.463 ALS2CR12 2:202163482 cg07227024 141394 −0.463 4:82273176 cg07454933 145378 −0.456 CPO 2:207803547 cg17600943 321671 −0.455 FAM19A5 22:48896579 cg11019791 208228 −0.452 FHIT 3:60420416 cg16140565 297019 −0.443 6:75775380 cg15706692 289960 −0.439 ATP11A 13:113539522 cg21463262 382273 −0.435 PDHA2 4:96760945 cg10590622 201120 −0.433 CNTNAP5 2:124971544 cg01013522 21327 −0.432 COLEC11 2:3675155 cg10724632 203346 −0.432 RD3 1:211667751 cg22481673 397284 −0.424 RBM28 7:127950724 cg03119308 63402 −0.423 13:21896301 cg13730219 253914 −0.423 8:142283564 cg04123498 82844 −0.421 MYOCD 17:12562530 cg14192979 263428 −0.421 SLFN12 17:33734664 cg20086657 361521 −0.417 2:150845309 cg15958422 293993 −0.409 IFT43; TGFB3 14:76443578 cg21193926 378403 −0.405 FAM101A; NCOR2; 12:124810173 cg13127920 242348 ZNF664- FAM101A −0.403 SLC2A9 4:10009916 cg21795255 387383 −0.403 ATXN7L1 7:105306555 cg11957130 223895 −0.403 TRIM64C 11:49073835 cg06445586 125882 −0.400 HLA-A 6:29906977 cg26739327 466540 −0.394 SCN4B 11:118022607 cg22251955 394153 −0.392 LINC00254 16:1939295 cg10051493 191486 −0.391 MIR4457; TERT 5:1300309 cg14597862 271789 −0.390 14:22279816 cg16423096 302000 −0.384 RPL27A; SNORA3; 11:8714324 cg15828613 291887 SNORA45; ST5 −0.382 MXRA7 17:74679597 cg03810198 76895 −0.378 CD82 11:44649802 cg21974656 390131 −0.377 BPIFA2 20:31755943 cg05840533 115130 −0.377 CCDC109B 4:110524473 cg17082366 313142 −0.375 TRIM24 7:138229989 cg12743416 236587 −0.374 RPTOR 17:78935070 cg17906851 326284 −0.371 KDM2B 12:121893769 cg07741840 150784 −0.370 HCG4B 6:29895204 cg26121931 455779 −0.369 NSMCE4A 10:123731471 cg19360212 349382 −0.369 NMNAT3 3:139397901 cg15295200 283344 −0.366 12:25454990 cg25134647 440489 −0.365 6:55778951 cg11290949 212735 −0.361 MRPL23 11:1985287 cg06258939 122771 −0.351 4:8569129 cg06991380 136538 −0.350 CDH4; MIR1257 20:60520624 cg16423285 302003 −0.349 MAST2 1:46420220 cg22337626 395319 −0.346 KIAA1908; PSMG3 7:1616229 cg23403836 412403 −0.346 SUMO3; UBE2G2 21:46220161 cg00272795 5810 −0.337 OR10K1 1:158435277 cg01463139 30452 −0.337 SLCO2B1 11:74861433 cg20704148 370892 −0.329 SPATS2L 2:201289756 cg17174466 314712 −0.327 SFT2D3; WDR33 2:128453335 cg03738707 75556 −0.325 HLA-DRB1 6:32555411 cg00598125 12786 −0.323 CCHCR1; PSORS1C2 6:31107186 cg07414487 144678 −0.322 HLA-A 6:29913343 cg19585676 353041 −0.320 LOC100628307 14:80858152 cg07572984 147668 −0.318 PSORS1C3 6:31148606 cg01982166 40677 −0.313 PTGER3; ZRANB2- 1:71511514 cg11418303 214891 AS1 −0.313 10:131209556 cg02372404 48486 −0.310 7:158750985 cg00413089 8734 −0.307 HCG4B 6:29894152 cg25644740 448500 −0.305 2:5605864 cg23233416 409551 −0.305 SLC47A2 17:19620263 cg08102564 157230 −0.302 SYS1; SYS1- 20:44007674 cg17811452 324650 DBNDD2; TP53TG5 −0.301 COL4A2 13:111115558 cg07618759 148582 −0.300 CDCA8; EPHA10 1:38180356 cg06437931 125736 −0.300 RPTOR 17:78809403 cg20502501 367732 −0.299 NDRG4 16:58534681 cg00758881 16033 −0.296 ITIH1; ITIH3 3:52828628 cg05393861 107345 −0.296 DPM2; FAM102A 9:130705120 cg01681863 34567 −0.295 TTC34 1:2710376 cg21783012 387180 −0.292 HCG4B 6:29895175 cg23681866 416899 −0.290 HCG4B 6:29895187 cg15411272 285048 −0.288 PSMD9; WDR66 12:122356390 cg21171335 377993 −0.286 BOC 3:112927486 cg27187580 474373 −0.286 MCF2L 13:113688132 cg15388766 284663 −0.285 B4GALNT4 11:364752 cg25497175 446150 −0.283 8:92570895 cg11420142 214927 −0.281 7:158751184 cg12744031 236605 −0.279 13:27077539 cg03531388 71371 −0.278 CASP7 10:115465924 cg01128042 23762 −0.278 HCG4B 6:29895260 cg24838316 435648 −0.278 2:69440951 cg02444957 49778 −0.277 OR51A2; OR51A4 11:4976263 cg25641451 448448 −0.274 FRMD4A 10:13972210 cg07629776 148782 −0.274 22:25571929 cg19707653 355076 −0.272 ATHL1; NLRP6 11:285037 cg22280068 394534 −0.269 SORBS2 4:186549051 cg09120722 175360 −0.267 11:5384517 cg26567385 463630 −0.265 MRPL44; WDFY1 2:224813276 cg15176306 281664 −0.265 19:29218101 cg04546413 91043 −0.264 10:47964834 cg16435686 302231 −0.264 7:158750244 cg12954512 239779 −0.263 16:14380714 cg03940883 79274 −0.262 B4GALT6 18:29205358 cg11986743 224388 −0.261 FBRSL1 12:133078117 cg23836570 419138 −0.259 LOC440905 2:130795582 cg18480627 335932 −0.257 SLC27A1 19:17600122 cg02707854 55128 −0.257 5:54117761 cg25997988 453719 −0.257 ATOH1 4:94759825 cg05893845 116159 −0.256 LOC100289473 20:1757570 cg03299990 66803 −0.252 COL18A1 21:46921982 cg05638648 111601 −0.251 7:1923695 cg12169700 227539 −0.250 C1orf86; PRKCZ 1:2121039 cg26227225 457598 −0.248 5:31106255 cg12908908 239081 −0.247 FAM157B 9:141105974 cg04824555 96218 −0.247 7:1976457 cg03075889 62651 −0.246 SLC6A3 5:1420305 cg07664579 149363 −0.245 ADAMTS2 5:178565001 cg01387905 28837 −0.243 7:136832262 cg05364766 106693 −0.241 19:13276344 cg19225953 347327 −0.241 PSMD9; WDR66 12:122356400 cg22618164 399325 −0.239 4:9479622 cg01394167 28957 −0.239 12:125411922 cg07877257 153188 −0.238 7:158750607 cg00815399 17228 −0.238 RNF213 17:78264297 cg11606607 217718 −0.237 TMEM39B 1:32535981 cg10312513 196231 −0.234 LPIN1 2:11888753 cg00523161 11124 −0.234 SGK110 19:56061334 cg18795732 340965 −0.232 LOC154822; VIPR2 7:158821175 cg25909532 452273 −0.231 7:158750384 cg11945929 223689 −0.229 1:161410551 cg22730047 401169 −0.228 PLEC 8:145003776 cg18000391 327713 −0.227 17:80849463 cg14195178 263473 −0.226 HOXA3; HOXA4; 7:27170394 cg19142026 346203 LOC100133311 −0.225 6:16962712 cg19300401 348504 −0.225 FAM66A 8:12237626 cg10206627 194443 −0.223 HTATIP2 11:20384377 cg26155681 456393 −0.221 AP2A2 11:970389 cg12893697 238836 −0.220 COL4A2 13:111111172 cg19218082 347212 −0.218 PAPLN 14:73712902 cg14834903 275901 −0.218 OSBPL5 11:3174092 cg06120313 120406 −0.217 C1orf86; PRKCZ 1:2120985 cg20300514 364680 −0.217 7:1367727 cg23896876 420086 −0.216 EGLN2; MIA- 19:41307778 cg21653913 385460 RAB4B; RAB4B; RAB4B- EGLN2 −0.216 13:80755568 cg00750481 15862 −0.216 5:176099987 cg11583351 217324 −0.215 5:125171542 cg12599971 234303 −0.215 MYO1D 17:31149877 cg01050010 22131 −0.213 DPYSL4; JAKMIP3 10:134001728 cg10144198 193247 −0.213 19:21863715 cg26562263 463546 −0.213 NDRG4 16:58533979 cg27113419 473118 −0.212 BMP4 14:54410717 cg16720578 307533 −0.210 5:134388224 cg03827835 77177 −0.209 C1orf86; PRKCZ 1:2121349 cg05337761 106096 −0.209 SFT2D3; WDR33 2:128453445 cg11059159 208817 −0.208 APOA1; APOC3; 11:116708413 cg09558982 183152 SIK3 −0.207 SFT2D3; WDR33 2:128453484 cg25277809 442618 −0.206 7:158750417 cg10079374 191993 −0.205 10:43522343 cg08461752 163848 −0.205 LASP1 17:37024042 cg20826740 372827 −0.204 NSUN4 1:46807113 cg17806798 324558 −0.204 1:149145082 cg16661522 306375 −0.204 PTP4A3 8:142427117 cg04687040 93680 −0.204 5:92414398 cg18783429 340738 −0.203 FLJ37453 1:16154831 cg21385522 381217 −0.203 12:132869069 cg05948955 117271 −0.202 RADIL 7:4854126 cg08799816 169789 −0.202 1:34615965 cg21440084 381930 −0.201 ARHGEF40; C14orf176; 14:21567333 cg00968545 20358 ZNF219 −0.200 7:1948755 cg16178271 297641 −0.199 TNS1 2:218707806 cg17588704 321484 −0.198 HLA-C 6:31241294 cg05338672 106118 −0.197 SLC27A1 19:17599784 cg17132030 313955 −0.196 11:19699299 cg18593660 337773 −0.196 16:1797050 cg07869343 153029 −0.195 GAS2L2; RASL10B 17:34067305 cg23633026 415965 −0.195 7:158790006 cg09640425 184513 −0.195 LRRC27 10:134150581 cg25076597 439582 −0.194 LOC440905 2:130795350 cg25180228 441163 −0.194 ZC3H12D 6:149785754 cg24131442 424218 −0.193 CES1 16:55867072 cg03744383 75666 −0.193 ACSF3 16:89152443 cg00324979 6844 −0.192 16:56000067 cg00991179 20841 −0.192 AP2A2 11:970664 cg06064525 119407 −0.192 CHTOP; S100A1; 1:153599704 cg11343894 213623 S100A13 −0.190 DBNL; PGAM2; 7:44104860 cg07075347 138233 POLM −0.189 MYO10 5:16895511 cg02288345 46701 −0.189 19:29218262 cg14983838 278359 −0.189 EIF2D 1:206786180 cg21936179 389599 −0.189 FN3K; TBCD 17:80708632 cg02398342 49038 −0.188 TM7SF4 8:105342491 cg04554929 91221 −0.187 NXN 17:707141 cg20403644 366219 −0.187 NFATC1 18:77292443 cg06675417 130167 −0.186 KIAA1751 1:1886501 cg06090818 119880 −0.185 LOC100507055 12:133180238 cg26621607 464484 −0.185 SLC9A3 5:502291 cg14137381 262235 −0.184 CLDN22; CLDN24; 4:184250312 cg14241748 264522 WWC2 −0.184 MMD2 7:5000111 cg02276823 46453 −0.184 COL5A1 9:137691430 cg13889467 257004 −0.184 6:30000187 cg01915885 39235 −0.184 SLC47A2 17:19627822 cg12434897 231546 −0.183 KRTAP4-7 17:39240789 cg23827950 418999 −0.182 19:29218302 cg12756686 236783 −0.182 GAB2 11:78052863 cg24769381 434565 −0.182 13:33854227 cg15405588 284964 −0.182 13:112978703 cg19891452 358388 −0.180 C11orf53 11:111148753 cg27649396 482130 −0.179 19:29218774 cg03161606 64225 −0.178 ADAP1; COX19 7:1003645 cg08735705 168762 −0.178 MTG1; PAOX 10:135202877 cg06080948 119697 −0.177 NEUROG3 10:71339632 cg02330874 47587 −0.177 C10orf96 10:118084587 cg02721176 55417 −0.177 BAI1 8:143546858 cg02048922 41986 −0.176 8:119750651 cg26711508 466113 −0.176 GPR50 X:150351493 cg20071203 361302 −0.175 LARS2 3:45429626 cg13510812 249280 −0.175 TUBG2 17:40808068 cg24417155 428624 −0.175 OR12D2 6:29364799 cg25786333 450628 −0.174 RASA3 13:114872606 cg27086157 472626 −0.174 C21orf128; UMODL1 21:43529162 cg02489157 50718 −0.174 MYT1L 2:2119533 cg26383138 460416 −0.174 10:125751386 cg00502035 10662 −0.174 7:102134668 cg17207545 315260 −0.173 NRG1 8:32579253 cg20127899 362151 −0.173 CHTOP; S100A1; 1:153599671 cg13946767 258256 S100A13 −0.173 APOA1BP; IQGAP3; 1:156551787 cg09319828 178942 TTC24 −0.172 ATP11A 13:113413587 cg08484560 164316 −0.171 NKX2-3 10:101287609 cg10947831 206964 −0.171 5:171057282 cg10881242 205925 −0.171 ADAP1; COX19 7:1003710 cg12575883 233841 −0.171 CRAMP1L; HN1L 16:1722957 cg04245870 85306 −0.170 ADAMTS7 15:79107452 cg23450377 413109 −0.170 PCSK6 15:101932559 cg27370471 477437 −0.170 19:1737123 cg08692111 167944 −0.170 C5orf38; IRX2 5:2743124 cg18803147 341088 −0.169 BAI1 8:143581481 cg26953288 470357 −0.169 STK32B 4:5374425 cg14422932 268145 −0.168 X:152584950 cg03201165 64963 −0.168 POU5F1; PSORS1C3 6:31146845 cg20073472 361344 −0.168 NDRG4 16:58534708 cg04484415 89876 −0.168 FAM20C 7:194798 cg12042135 225245 −0.167 EDN1 6:12292676 cg27565517 480713 −0.167 C1QTNF8 16:1152511 cg06394109 125022 −0.167 KLK5; KLK6 19:51456308 cg00768359 16234 −0.166 ADAP1 7:961457 cg06589239 128495 −0.166 11:134892703 cg21757617 386803 −0.166 HOXA3; HOXA4; 7:27170892 cg14359292 266882 HOXA5; LOC100133311 −0.165 LCP1 13:46757415 cg06477663 126420 −0.165 SPAG11A 8:7720259 cg23703303 417310 −0.165 19:21767566 cg19051117 344954 −0.165 OR10R2 1:158450237 cg04132017 83014 −0.165 LOC284661 1:4481995 cg20252997 363933 −0.164 FHOD3 18:34327498 cg21367586 380971 −0.164 PCDHB4 5:140501812 cg06048354 119137 −0.164 HLA-DQB2 6:32729174 cg04418355 88678 −0.164 6:28447087 cg26968378 470632 −0.163 BAI1 8:143580965 cg09544050 182856 −0.163 LOC440905 2:130794753 cg25239986 442097 −0.163 SPINK5 5:147473666 cg04829448 96297 −0.163 ZNF718 4:124342 cg12717203 236185 −0.163 TIAM2 6:155464712 cg24207161 425489 −0.162 PACS2 14:105830721 cg19499452 351610 −0.162 MCTS1 X:119738550 cg00357087 7563 −0.162 RASA3 13:114900021 cg06611532 128857 −0.161 4:187984958 cg19632603 353880 −0.160 ITGA11 15:68713677 cg02454536 49961 −0.160 ACAP1; KCTD11; 17:7253720 cg02676175 54546 TMEM95 −0.160 HAAO 2:43023945 cg14631114 272427 −0.160 WWP2 16:69830414 cg03424554 69244 −0.160 PGRMC2 4:129212177 cg02096220 43042 −0.159 SHISA6 17:11142733 cg23474049 413465 −0.159 6:28447107 cg12584458 233995 −0.159 ZP2 16:21222939 cg18249108 332126 −0.159 CLCNKA; HSPB7 1:16349079 cg08231696 159747 −0.158 SPINK7 5:147699718 cg08859406 170938 −0.158 GNAS 20:57463503 cg11480267 215775 −0.158 STX2 12:131303247 cg11011512 208090 −0.158 ADCK4 19:41208803 cg07615236 148518 −0.158 6:148540308 cg21796170 387391 −0.158 NDRG4 16:58534157 cg05725404 113149 −0.157 ANXA9; CERS2 1:150954826 cg13320146 245435 −0.157 SAMD3 6:130504413 cg24048806 422810 −0.157 TCL6 14:96129574 cg05093429 101497 −0.157 6:55761410 cg17273096 316241 −0.156 B3GNTL1 17:81008971 cg17652174 322327 −0.156 RNF219 13:79234251 cg01819759 37343 −0.156 GGNBP2; MYO19; 17:34891843 cg02097479 43078 PIGW −0.156 7:79964738 cg22110839 392010 −0.156 HOXA3; HOXA4; 7:27170412 cg11410718 214730 LOC100133311 −0.155 6:58777827 cg26951520 470325 −0.155 KIRREL3- 11:126872863 cg17273911 316252 AS3 −0.155 NRXN1 2:51260399 cg00345522 7288 −0.155 14:106025958 cg27055313 472099 −0.155 4:60001000 cg11281224 212579 −0.154 4:9479947 cg12006118 224679 −0.154 IL12RB1 19:18170383 cg26642774 464790 −0.154 1:22599443 cg07371337 143948 −0.154 ZNF845 19:53828996 cg22256944 394221 −0.154 13:112705636 cg01896130 38843 −0.154 HOTAIR; HOXC12 12:54354590 cg05573844 110417 −0.154 13:61758710 cg15508935 286618 −0.154 MICA 6:31382027 cg20144487 362399 −0.153 6:156983263 cg05282260 105071 −0.153 MIR1283- 19:54199538 cg26325497 459342 1; MIR518B; MIR518F; MIR519B; MIR519C; MIR520A; MIR520B; MIR523; MIR525; MIR526A1; MIR526B −0.153 MKX 10:28030033 cg13806489 255420 −0.153 10:53639124 cg06976598 136324 −0.153 CHTOP; S100A1; 1:153600156 cg07898899 153567 S100A13 −0.152 11:24346161 cg05202300 103488 −0.152 LOC728613 5:1641766 cg08769156 169313 −0.152 LOC100506388; 17:184106 cg15996459 294655 RPH3AL −0.151 PALMD 1:100111849 cg24603803 431699 −0.151 HCG4B 6:29895116 cg15671450 289296 −0.151 8:88760082 cg05893029 116145 −0.150 GPR158 10:25620462 cg01006048 21182 −0.150 14:95155784 cg16462006 302671 −0.150 PALM2; PALM2- 9:112562314 cg13690280 253070 AKAP2 −0.150 LOC100507055; 12:133185615 cg18833933 341613 P2RX2 −0.150 IGF2; IGF2- 11:2154132 cg11717189 219595 AS; INS- IGF2; MIR483 −0.149 MYO16 13:109833854 cg10697882 202881 −0.149 SUMO3 21:46239952 cg22595657 398990 −0.149 EME2; MRPS34; 16:1822124 cg09540102 182804 NME3; SPSB3 −0.149 TTLL10 1:1118157 cg16366262 300931 −0.149 7:158269409 cg17429772 318912 −0.149 12:133003907 cg04741728 94673 −0.148 SHANK2 11:70493931 cg05794931 114366 −0.148 CRTAC1 10:99734513 cg19421526 350393 −0.148 PXDN 2:1734344 cg12760299 236833 −0.148 6:28447115 cg21903646 389050 −0.148 GGNBP1; LINC00336 6:33561099 cg04329454 86936 −0.148 CLGN 4:141317067 cg22901919 403995 −0.147 COL11A2; RXRB 6:33158020 cg16507569 303394 −0.147 7:93960063 cg01827933 37531 −0.147 LHX6 9:124983482 cg13832372 255929 −0.147 ISL1 5:50688913 cg26293019 458765 −0.147 DBNL; PGAM2; 7:44105050 cg16627090 305718 POLM −0.147 3:193587490 cg21197336 378486 −0.147 14:107095056 cg07958169 154668 −0.147 SNED1 2:241975140 cg09991306 190473 −0.147 HOXA3; HOXA4; 7:27170755 cg03724423 75252 HOXA5; LOC100133311 −0.147 SEPT3; WBP2NL 22:42395067 cg22189786 393238 −0.147 2:208541770 cg03716125 75048 −0.146 5:66541588 cg11553311 216848 −0.146 KTN1; KTN1- 14:56046098 cg16907514 310470 AS1 −0.146 FAM116B; PLXNB2 22:50753068 cg20435485 366698 −0.146 HOXA3; HOXA4; 7:27170388 cg07317062 142981 LOC100133311 −0.145 HLA-A 6:29911295 cg09535358 182715 −0.145 ARNTL 11:13302098 cg13286116 244869 −0.145 MSH5; MSH5- 6:31731881 cg03392100 68641 SAPCD1; SAPCD1; VWA7 −0.145 IL31; LRRC43 12:122651623 cg14874216 276626 −0.145 MSH5; MSH5- 6:31734192 cg13187827 243288 SAPCD1; SAPCD1; VWA7 −0.144 SERPINB6 6:2972435 cg08155050 158293 −0.144 DLGAP2 8:1455764 cg10636144 201951 −0.144 SAMD11 1:869368 cg13692836 253138 −0.144 RPH3AL 17:146926 cg04172345 83843 −0.144 1:228743235 cg12437277 231594 −0.143 17:79455736 cg09841001 187897 −0.143 C11orf53; C11orf92 11:111155021 cg03554573 71909 −0.143 ATXN1 6:16413624 cg11291305 212741 −0.143 FEM1A 19:4785374 cg14818248 275598 −0.143 HLA-A 6:29912713 cg18349863 333730 −0.143 TP73 1:3600879 cg17471939 319626 −0.143 1:2863815 cg25137787 440554 −0.143 ARNT2 15:80824318 cg19708986 355104 −0.143 13:99084682 cg03040740 61905 −0.143 6:28446840 cg01792601 36700 −0.142 LRRC15 3:194091167 cg07048348 137676 −0.142 1:37231474 cg21952052 389839 −0.142 DFNA5 7:24742552 cg25709790 449401 −0.142 PACS2 14:105830606 cg12425861 231390 −0.142 INPP5K; LOC100306951; 17:1412950 cg07185664 140562 PITPNA −0.141 LOC100506388; 17:184131 cg24871089 436253 RPH3AL −0.141 DDX58 9:32525315 cg14286514 265460 −0.141 7:158789849 cg19418458 350346 −0.141 ARHGAP30; PVRL4 1:161042063 cg00862398 18157 −0.141 IKZF3; ZPBP2 17:38024146 cg16810031 309049 −0.141 17:21416281 cg00007215 167 −0.141 8:23605601 cg03324961 67319 −0.141 PDE6B 4:645781 cg01132407 23844 −0.140 HHIPL1 14:100130465 cg18678107 339014 −0.140 MTG1; PAOX 10:135202906 cg24644436 432348 −0.140 CES1 16:55866757 cg03880033 78129 −0.139 TLX1NB 10:102872719 cg17034508 312397 −0.139 PCDHB17; PCDHB6 5:140530410 cg23247945 409860 −0.139 TMEM100 17:53800484 cg18040354 328429 −0.139 PRKG2 4:82075193 cg22772235 401742 −0.139 SEL1L2 20:13830102 cg17971895 327285 −0.139 5:74908142 cg19683494 354666 −0.139 2:131010647 cg27624826 481683 −0.139 HIPK4; PRX 19:40904691 cg24923931 437130 −0.138 SCN7A 2:167350883 cg14771658 274784 −0.138 15:98196247 cg19459332 350984 −0.137 PMPCA; SDCCAG3; 9:139299357 cg14108380 261681 SNAPC4 −0.137 16:62984521 cg02248103 45873 −0.137 CYB5D2; ZZEF1 17:4043867 cg04417708 88669 −0.137 CST11; CSTL1 20:23433608 cg11657817 218579 −0.137 CTC1; LINC00324 17:8124867 cg20250341 363887 −0.137 CNR2; FUCA1 1:24195143 cg24792360 434918 −0.137 PKNOX2 11:125170859 cg23418965 412666 −0.137 PAX2 10:102592366 cg03286031 66537 −0.137 TEX2 17:62341028 cg18312782 333101 −0.137 2:226913713 cg05293897 105270 −0.136 TMEM72-AS1 10:45374906 cg20638675 369712 −0.136 HLA-DQB2 6:32729130 cg07180897 140474 −0.136 ALK 2:29751968 cg01412762 29371 −0.136 19:29218732 cg12667521 235503 −0.136 TOX2 20:42548586 cg20889774 373555 −0.136 RECK 9:36036514 cg13392078 246714 −0.136 MIR593 7:127720749 cg20426275 366531 −0.136 ODZ4 11:78948859 cg12642289 235052 −0.136 MTERF 7:91510405 cg16284459 299467 −0.136 RBFOX3 17:77302162 cg08223357 159591 −0.136 18:44770781 cg24371990 427906 −0.136 CACNA1C 12:2696048 cg08166587 158536 −0.136 DAB1 1:58089001 cg00026909 659 −0.135 6:156983304 cg08839808 170533 −0.135 MTG1; PAOX 10:135202839 cg17143376 314138 −0.135 PIP5K1A; VPS72 1:151170427 cg24720336 433732 −0.135 ANKS3; C16orf71; 16:4793770 cg00605362 12928 ZNF500 −0.135 11:91950460 cg20506843 367791 −0.135 RTN4RL1 17:1835482 cg23676314 416771 −0.135 2:10984512 cg00442205 9317 −0.134 ZDHHC13 11:19138045 cg00161556 3630 −0.134 PAPLN 14:73712491 cg09636214 184437 −0.134 CTRB2 16:75242114 cg08467866 163985 −0.133 ZNF718 4:125112 cg10197305 194260 −0.133 IGF2; IGF2- 11:2154113 cg13165070 242895 AS; INS- IGF2; MIR483 −0.133 2:38099030 cg02752932 56067 −0.133 TACC2 10:123873748 cg23828763 419014 −0.133 7:115116310 cg04544267 91006 −0.133 CES1 16:55866997 cg23196985 408839 −0.133 CCDC105 19:15121385 cg18739061 339959 −0.133 19:43203368 cg24333150 427217 −0.132 FXYD2; FXYD6- 11:117696743 cg11820026 221463 FXYD2 −0.132 DAB2IP 9:124363848 cg21234082 379229 −0.132 LOC100289187 7:99195819 cg12290671 229416 −0.132 OCA2 15:28014040 cg15194100 281887 −0.132 NAV1 1:201644923 cg24253904 426103 −0.132 SLC24A6 12:113773298 cg12583184 233973 −0.131 3:42265641 cg18812386 341259 −0.131 GREB1; MIR4429 2:11680020 cg11534680 216555 −0.131 TXNRD1 12:104676774 cg15775217 291055 −0.131 CCBL2; RBMXL1 1:89459529 cg11309454 213030 −0.131 GPR12 13:27338713 cg14339397 266524 −0.131 9:34810228 cg13923371 257761 −0.131 IFI44; IFI44L 1:79114976 cg07107453 138862 −0.130 5:171057196 cg07871442 153079 −0.130 OVCH2 11:7709186 cg25833922 451333 −0.130 PSMD11 17:30770961 cg09309269 178739 −0.130 DEFA4; DEFA6 8:6783521 cg02932321 59694 −0.130 TEPP 16:58016655 cg01479664 30752 −0.130 IL28B 19:39737768 cg04722177 94275 −0.130 IL20RA 6:137366545 cg08823985 170226 −0.130 PA2G4; RPL41; 12:56509603 cg18500368 336269 ZC3H10 −0.129 14:26338282 cg16725552 307629 −0.129 ATHL1; NLRP6 11:281516 cg06432119 125636 −0.129 GIMAP4 7:150264767 cg08960815 172781 −0.129 KLHL29 2:23839710 cg01387450 28832 −0.129 12:114701413 cg10233830 194930 −0.129 2:62521325 cg22770637 401725 −0.129 ALK 2:30142677 cg00643897 13652 −0.129 SEMA5B 3:122712271 cg11160908 210504 −0.129 TTF2 1:117604726 cg19319037 348805 −0.129 C20orf54 20:741798 cg19037007 344707 −0.129 12:69725435 cg22375663 395880 −0.129 8:41585554 cg17182837 314877 −0.128 3:118144311 cg20207443 363278 −0.128 LINC00299 2:8444004 cg18854004 341911 −0.128 11:106239635 cg01152624 24270 −0.128 GNAS; GNAS- 20:57431202 cg09437522 181002 AS1 −0.128 13:112978683 cg20923605 374019 −0.128 MITF 3:69915302 cg03831180 77231 −0.128 PTN 7:137029097 cg15284177 283213 −0.128 1:149155792 cg27554973 480528 −0.127 ENTPD1; LOC728558 10:97624891 cg09217157 177016 −0.127 ZFPM1 16:88536950 cg05183538 103174 −0.127 CCDC64B; HCFC1R1; 16:3079953 cg07063883 137997 THOC6; TNFRSF12A −0.127 APOA1BP; IQGAP3; 1:156551873 cg01010328 21258 TTC24 −0.127 NRG1 8:32076032 cg23964820 421269 −0.127 MTG1; PAOX 10:135203102 cg18563886 337268 −0.127 13:112984840 cg27260867 475484 −0.127 AKAP8; AKAP8L 19:15488902 cg22765626 401667 −0.127 18:37379468 cg15612221 288285 −0.127 17:21416258 cg10674575 202559 −0.127 13:100583872 cg07223206 141319 −0.126 KLK1; KLK15 19:51334890 cg26325285 459337 −0.126 GALNT9; LOC100130238 12:132859608 cg10173694 193804 −0.126 ATG4C 1:63249199 cg24082680 423369 −0.126 7:102330635 cg06322601 123757 −0.126 3:73723546 cg02131018 43720 −0.126 HIPK4; PRX 19:40904851 cg00478479 10159 −0.126 GNAT1; SLC38A3 3:50242325 cg15335139 283889 −0.126 CYP4F30P 2:131451149 cg14204395 263669 −0.126 16:88804051 cg26748794 466680 −0.126 HUNK 21:33242495 cg15636421 288718 −0.125 KLHL29 2:23840282 cg17129809 313908 −0.125 MEIS1 2:66657913 cg10835286 205203 −0.125 NUP98; PGAP2 11:3817849 cg19247588 347686 −0.125 MIR4287; SCARA5 8:27735178 cg04214878 84655 −0.125 SPINK7 5:147699892 cg13022905 240779 −0.125 PTH1R 3:46936655 cg02527881 51488 −0.125 GIMAP4 7:150264987 cg00323915 6821 −0.125 PTHLH 12:28120054 cg20389635 366021 −0.125 EIF2D 1:206786174 cg16966520 311311 −0.124 7:27475596 cg10070328 191836 −0.124 1:161409970 cg00975746 20506 −0.124 KCNK10 14:88791298 cg02883668 58609 −0.124 15:34788847 cg10767425 203961 −0.124 8:49044542 cg11491002 215895 −0.124 DLGAP4 20:35064637 cg01463540 30456 −0.124 HSP90B3P 1:92099858 cg04090794 82132 −0.124 NOSIP; PRRG2 19:50084626 cg21913888 389236 −0.124 ISL1 5:50692281 cg24549912 430883 −0.124 STC2 5:172751331 cg01984743 40717 −0.124 2:72079276 cg07258910 141932 −0.123 PKD1L2 16:81254169 cg03406106 68931 −0.123 ANO4 12:101187093 cg25027699 438862 −0.123 TRIM21 11:4415203 cg07244098 141703 −0.123 MRPL38; TRIM65 17:73892097 cg01453052 30258 −0.123 BTN3A3 6:26442290 cg12537337 233273 −0.123 LOC100129620; 1:99469634 cg24373253 427922 LPPR5 −0.123 FYN 6:112165062 cg26846943 468428 −0.123 ASB1 2:239334832 cg08773314 169376 −0.123 FAM163A 1:179713788 cg14748380 274436 −0.122 KIAA1143; KIF15 3:44802604 cg09333631 179217 −0.122 MAP3K7 6:91297516 cg18683523 339091 −0.122 4:9382953 cg02136252 43830 −0.122 5:141616065 cg24749559 434242 −0.122 15:101389733 cg07035436 137452 −0.122 5:72510846 cg26653990 465004 −0.122 17:78955599 cg11521079 216324 −0.122 2:227476235 cg08982961 173162 −0.122 LRRC27 10:134150542 cg22586726 398883 −0.122 EXOC7; GALR2; 17:74073876 cg07909178 153763 SRP68; ZACN −0.121 TAF3 10:7859768 cg09994553 190530 −0.121 CDK12; MED1 17:37608096 cg15445000 285571 −0.121 HLA- 6:33043849 cg22483030 397307 DPA1; HLA- DPB1 −0.121 NUBP1 16:10837135 cg09079882 174735 −0.121 TSLP 5:110407538 cg15739437 290539 −0.121 PSMD9; WDR66 12:122356598 cg21016266 375557 −0.121 DOK7 4:3487436 cg15652666 289019 −0.121 OR6B3; PRR21 2:240985618 cg10906826 206344 −0.121 FBLN7 2:112898400 cg09982942 190323 −0.120 CXCR7 2:237478664 cg03626672 73351 −0.120 MBTPS2 X:21858304 cg21195120 378430 −0.120 NLRP3; OR2B11 1:247616686 cg14830002 275801 −0.120 CTAGE11P 13:75814496 cg17109374 313605 −0.120 5:177395755 cg11264997 212321 −0.120 GAS7; RCVRN 17:9805074 cg26853458 468546 −0.120 GAD2 10:26531942 cg23052437 406538 −0.120 LCE2A 1:152670843 cg13697387 253231 −0.120 SPDYC 11:64936920 cg23079866 407032 −0.119 SPTBN2 11:66487938 cg04883026 97440 −0.119 HOTTIP; HOXA11- 7:27236674 cg01363170 28338 AS1; HOXA13 −0.119 SYS1; SYS1- 20:43991402 cg00385441 8134 DBNDD2 −0.119 ZNF876P 4:204382 cg00569896 12104 −0.119 CCDC71; KLHDC8B 3:49203081 cg18590502 337716 −0.119 GRAMD2 15:72448319 cg12252008 228855 −0.119 16:76228294 cg06827491 133242 −0.119 LOC116437 12:131645153 cg07374109 143989 −0.119 CACNG4 17:64973939 cg23968154 421320 −0.119 NAV1 1:201619295 cg04179952 83989 −0.119 12:58934471 cg01919941 39316 −0.119 13:21893289 cg21970626 390084 −0.119 ANXA9; FAM63A 1:150969592 cg21859421 388363 −0.119 1:10895517 cg17480077 319783 −0.118 LRRC27 10:134150489 cg21370255 381012 −0.118 POTEA 8:43147397 cg26969150 470647 −0.118 HOXA3; HOXA4; 7:27170313 cg04317399 86720 LOC100133311 −0.118 C1orf86; PRKCZ 1:2121449 cg08200543 159156 −0.118 8:81143546 cg16745033 307963 −0.118 7:136362483 cg11678250 218935 −0.118 SPIN2B X:57147918 cg12074688 225883 −0.118 8:144152376 cg17001448 311828 −0.118 ASPHD1; KCTD13; 16:29912700 cg10093648 192261 SEZ6L2 −0.118 EIF2D 1:206786178 cg16639185 305935 −0.118 PXN 12:120688744 cg22564731 398621 −0.118 MIR4757; OSR1 2:19553950 cg00954878 20061 −0.118 PROX1 1:214152805 cg26054764 454613 −0.117 CDH3 16:68691561 cg09821218 187538 −0.117 LPP 3:188115336 cg23651889 416316 −0.117 5:72666838 cg11316517 213156 −0.117 DSCR3 21:38630506 cg18380783 334168 −0.117 7:136190456 cg03439301 69540 −0.117 TMEM100 17:53800554 cg03233426 65601 −0.117 PSMD11 17:30770932 cg20190559 363067 −0.117 5:171057078 cg11620716 217943 −0.117 FN3K; TBCD 17:80708513 cg00809820 17098 −0.117 SECTM1 17:80285515 cg05744064 113450 −0.117 NCOA1 2:24806444 cg23648923 416268 −0.117 LOC100128398; 19:58515046 cg09577391 183474 ZNF606 −0.117 LOC100289187 7:99195788 cg24024660 422355 −0.117 16:77535527 cg06794141 132525 −0.117 2:192792315 cg01836906 37718 −0.117 LELP1 1:153175842 cg00298977 6302 −0.117 ODF1 8:103556749 cg27000960 471198 −0.117 GCK 7:44229319 cg16476432 302901 −0.117 11:2211939 cg19586845 353065 −0.117 HCG4; LOC554223 6:29761905 cg25193571 441364 −0.117 CTNND2 5:11588971 cg01937840 39702 −0.116 MYOM2 8:1994478 cg20219329 363455 −0.116 15:30337018 cg14398295 267622 −0.116 RASAL1 12:113574368 cg16890739 310176 −0.116 15:36699121 cg02763009 56272 −0.116 BIRC7; FLJ16779; 20:61878032 cg12649455 235197 MIR3196; NKAIN4 −0.116 7:1250246 cg07034004 137422 −0.116 5:170763642 cg23036405 406232 −0.116 NCR1 19:55417647 cg12952132 239747 −0.116 1:22591361 cg13048466 241145 −0.115 GLP1R 6:39015339 cg19772011 356340 −0.115 RGMA 15:93615146 cg21079003 376460 −0.115 PGM5P2 9:69148624 cg18861917 342052 −0.115 ZBED4 22:50250283 cg20618087 369398 −0.115 LARS2 3:45429742 cg04459086 89409 −0.115 TACC2 10:123886914 cg26111575 455575 −0.115 ST8SIA2 15:92939006 cg08289525 160900 −0.115 ANO7 2:242147702 cg00255732 5474 −0.115 LRRC34; LRRIQ4 3:169531864 cg10994914 207829 −0.115 14:88097221 cg26252794 458035 −0.115 DGKB 7:14415317 cg03229767 65553 −0.114 LRRC27 10:134150690 cg02535060 51631 −0.114 LOC100131138 12:111374169 cg09792970 187023 −0.114 CNNM2 10:104676907 cg15439196 285445 −0.114 CCNYL1 2:208572165 cg18757817 340266 −0.114 PRRX1 1:170631847 cg22693806 400548 −0.114 11:44489577 cg03708694 74912 −0.114 DKFZp434L192 7:56563820 cg21216010 378877 −0.114 NRP1 10:33612892 cg17425818 318845 −0.114 TFCP2 12:51570174 cg21570277 384054 −0.114 LHX6 9:124982834 cg17930194 326612 −0.114 MMP17 12:132317128 cg01830463 37580 −0.114 LRRC27 10:134150567 cg07119315 139090 −0.114 8:67317506 cg02934300 59732 −0.114 DBNL; PGAM2; 7:44105721 cg21088488 376592 POLM −0.114 1:113425263 cg10541466 200276 −0.114 AGAP1 2:236774164 cg03785646 76466 −0.114 7:73424891 cg09076650 174691 −0.114 6:1449399 cg18182981 331002 −0.114 NDUFA12 12:95397704 cg22141781 392510 −0.114 HOXA3; HOXA4; 7:27170880 cg04321618 86813 HOXA5; LOC100133311 −0.113 MIR4283- 7:63085215 cg10945855 206928 1; MIR4283-2 −0.113 PPIL2 22:22020076 cg04983276 99379 −0.113 2:72079413 cg24516106 430249 −0.113 10:125222790 cg11653519 218499 −0.113 7:21209781 cg08701183 168131 −0.113 MTG1; PAOX 10:135202522 cg10902549 206273 −0.113 NR2F1 5:92927796 cg26067259 454804 −0.113 2:218048915 cg00549040 11649 −0.113 GRK4 4:3043527 cg01807241 37046 −0.113 TNXB 6:32066446 cg14011987 259623 −0.113 SNED1 2:241975756 cg26707709 466046 −0.113 6:28446794 cg03350138 67869 −0.113 C6orf48; HSPA1B; 6:31806478 cg17794996 324365 SNORD48; SNORD52 −0.113 CBX7 22:39545030 cg18708252 339475 −0.113 UPF2 10:12085641 cg00513208 339475 −0.113 17:80860250 cg04497611 90135 −0.112 DMD X:31285129 cg06746884 131521 −0.112 FGF4 11:69587473 cg26765567 466900 −0.112 6:30419373 cg03507875 70857 −0.112 19:29217858 cg25267487 442467 −0.112 16:84953424 cg01765164 36115 −0.112 DGKG 3:185912486 cg18172135 330799 −0.112 13:111451972 cg22731513 401204 −0.112 FZD1 7:90895894 cg08714590 168374 −0.112 CLCN7 16:1524255 cg08008072 155549 −0.112 CRX 19:48324309 cg06945747 135695 −0.112 1:91227319 cg08895590 171690 −0.112 KALRN 3:124232190 cg06690085 130439 −0.112 9:128799328 cg13946341 258251 −0.112 IL34; MTSS1L 16:70688171 cg02602352 52989 −0.112 TMEM171 5:72431891 cg01170694 24642 −0.112 17:42706084 cg14836839 275934 −0.112 RASGEF1C 5:179634671 cg12408990 231108 −0.112 DOK7 4:3486116 cg00752263 15898 −0.112 ANAPC2; GRIN1; 9:140062197 cg03206445 65043 LRRC26; MIR3621 −0.111 OR6Q1; OR9Q1 11:57792403 cg18886347 342489 −0.111 BAI1 8:143580823 cg05758861 113684 −0.111 2:121280002 cg00314115 6610 −0.111 MUC22 6:30980847 cg27292220 475981 −0.111 AGAP1 2:236773924 cg15981851 294380 −0.111 6:55774999 cg19318364 348791 −0.111 ITIH1; ITIH3 3:52824283 cg18404041 334584 −0.111 PDE6B 4:648752 cg17643796 322207 −0.111 TRIM7 5:180614858 cg25606201 447878 −0.111 8:141490124 cg15842218 292164 −0.111 IPMK 10:59949191 cg09039685 174085 −0.111 CCDC129 7:31685368 cg02943305 59917 −0.111 5:1645640 cg11628972 218045 −0.111 CDHR3 7:105596715 cg27099486 472857 −0.111 DCX X:110654011 cg11031647 208426 −0.111 PLA2G4D 15:42371967 cg02760164 56222 −0.111 ANKRD34C 15:79576704 cg14577319 271361 −0.110 1:161391807 cg00056433 1344 −0.110 FHL3; SF3A3 1:38460950 cg05202204 103487 −0.110 5:72485634 cg14727987 274140 −0.110 11:41481578 cg24638253 432227 −0.110 6:27521330 cg26264769 458241 −0.110 5:177592761 cg25087499 439729 −0.110 14:103783717 cg10559742 200586 −0.110 ARL4C 2:235406291 cg05308656 105595 −0.110 HHIP; LOC646576 4:145566595 cg02524475 51415 −0.110 C11orf9 11:61545187 cg07136108 139453 −0.110 PCDHA1; PCDHA10; 5:140238079 cg18906028 342772 PCDHA11; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9 −0.110 LOC151171 2:239463229 cg10182060 193967 −0.110 14:22385890 cg16138400 296975 −0.110 MAGIX; PLP2; X:49027884 cg22366498 395712 PRICKLE3 −0.110 COL1A1 17:48288538 cg06769994 132032 −0.110 FAM70A X:119443941 cg26583344 463923 −0.110 CXCR2 2:219001517 cg10819992 204935 −0.110 16:66162203 cg26798936 467489 −0.110 CCHCR1; PSORS1C2 6:31105872 cg03034365 61773 −0.110 3:36675685 cg12870891 238511 −0.110 DEFB135; DEFB136 8:11838843 cg12807628 237566 −0.110 MDC1; TUBB 6:30684572 cg10925640 206607 −0.110 CLDN4; WBSCR27 7:73256416 cg03781731 76399 −0.110 SNRPN 15:25123381 cg08560373 165668 −0.109 FBXL16; METRN 16:757149 cg07644125 149038 −0.109 EIF2D 1:206786170 cg21155316 377647 −0.109 8:135726252 cg00057272 1361 −0.109 13:112979998 cg20620751 369432 −0.109 DHRS7 14:60629192 cg06898279 134753 −0.109 EFS; IL25 14:23835595 cg17205324 315223 −0.109 PALMD 1:100111727 cg07960762 154721 −0.109 10:79470169 cg19094530 345528 −0.109 ARHGEF6 X:135863582 cg01134144 23879 −0.109 DUS3L 19:5799340 cg20467412 367204 −0.109 RGMA 15:93633408 cg04697454 93855 −0.109 VWA5B1 1:20608736 cg16713551 307396 −0.109 14:106791268 cg14042931 260352 −0.109 19:1673498 cg10697737 202878 −0.109 GPR4; OPA3 19:46097075 cg16620032 305585 −0.109 LOC388630 1:48452740 cg07202054 140866 −0.108 HK3; UNC5A 5:176314628 cg06783121 132285 −0.108 6:12342070 cg03519011 71096 −0.108 C12orf73; TDG 12:104350162 cg22927789 404375 −0.108 CDH22 20:44882514 cg25558663 447055 −0.108 6:18752614 cg00664117 14044 −0.108 ARHGEF25; B4GALNT1; 12:58011837 cg00700412 14808 DTX3; SLC26A10 −0.108 SHANK2 11:70564414 cg13080721 241684 −0.108 LOC154449 6:170571686 cg18698681 339306 −0.108 KCNH2 7:150644459 cg01559770 32264 −0.108 TMEM132D 12:130384734 cg08261450 160299 −0.108 DUOX1; DUOXA1 15:45427034 cg14918338 277309 −0.108 DNAJB13 11:73661250 cg02070028 42486 −0.108 PSMD7 16:74331618 cg09313046 178793 −0.108 LGR6 1:202172778 cg04811114 95994 −0.108 13:69557960 cg18586262 337639 −0.108 1:201316444 cg26233753 457728 −0.108 1:37139265 cg20745381 371614 −0.108 10:121837310 cg10087780 192116 −0.108 15:98196234 cg08064292 156507 −0.107 GUCY2E; LRRC32 11:76381800 cg19752094 355941 −0.107 LOC440910 2:132057004 cg07051654 137739 −0.107 NAPSA 19:50861262 cg12273319 229159 −0.107 TRIM69 15:45028270 cg10439456 198368 −0.107 CHTOP; S100A1; 1:153599831 cg02331910 47613 S100A13 −0.107 5:132938694 cg19005955 344221 −0.107 ACOT11; FAM151A 1:55096622 cg22619910 399357 −0.107 CRYBA2; FEV; 2:219851181 cg18664514 338819 LOC151300 −0.107 C10orf96 10:118084504 cg13836550 255997 −0.107 SORCS3 10:106749483 cg26349484 459830 −0.107 ZEB2; ZEB2- 2:145273345 cg04640885 92836 AS1 −0.107 GALNT6 12:51786489 cg15127250 280846 −0.107 3:137187558 cg24821307 435362 −0.107 ADORA1 1:203086869 cg18811731 341246 −0.107 OR1J4; OR1N1 9:125289357 cg14598387 271804 −0.107 CARTPT 5:71012177 cg11927345 223348 −0.107 HCRT; KCNH4 17:40330907 cg06514003 127062 −0.107 SNRPN 15:25093366 cg02171545 44484 −0.107 C2orf28; CAD; 2:27434262 cg14242246 264531 SLC5A6 −0.107 HOXA3; HOXA4; 7:27170552 cg16651126 306141 LOC100133311 −0.107 15:20562413 cg03344283 67729 −0.106 PLA2G7 6:46703670 cg12854458 238255 −0.106 MAG 19:35790951 cg25443560 445295 −0.106 HLA-DRB1 6:32552022 cg10765922 203924 −0.106 FAM83H; MAPK15 8:144801088 cg05626536 111385 −0.106 3:193987757 cg16282892 299443 −0.106 POU4F2 4:147573410 cg05710982 112882 −0.106 DKFZp434J0226 19:46712075 cg00537984 11421 −0.106 GPR31 6:167571630 cg25285053 442729 −0.106 PCDHA1; PCDHA10; 5:140248610 cg25024993 438807 PCDHA11; PCDHA12; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9 −0.106 SGPP2 2:223288637 cg11300809 212887 −0.106 DLC1 8:13373090 cg00933411 19610 −0.106 PRSS55 8:10386222 cg10657228 202268 −0.106 ZIC1; ZIC4 3:147120248 cg13897134 257142 −0.106 DKFZp434L192 7:56563742 cg17876758 325825 −0.106 C11orf10; C11orf9 11:61548003 cg19617373 353600 −0.106 6:99075228 cg05593122 110762 −0.106 14:104787388 cg05210671 103662 −0.106 HHLA2 3:108041508 cg24769830 434575 −0.106 LOC100506012; 19:46999055 cg03969996 79829 PNMAL2 −0.106 BEX5 X:101411275 cg03993934 80323 −0.106 15:98196333 cg11023328 208285 −0.105 ZIC5 13:100605441 cg10523198 199939 −0.105 TIGIT 3:114009756 cg05943254 117166 −0.105 CTNND2 5:11589049 cg17415451 318667 −0.105 MGC27382 1:78693899 cg22559013 398527 −0.105 DLC1 8:13372483 cg08768218 169300 −0.105 F10; F7 13:113783990 cg25796986 450780 −0.105 SOX2-OT 3:181417613 cg06283493 123126 −0.105 13:54898133 cg18817396 341362 −0.105 KIAA1143; KIF15 3:44802566 cg17546649 320901 −0.105 CRYAA 21:44593708 cg21895314 388915 −0.105 FOXS1 20:30437731 cg05366561 106738 −0.105 FIBIN 11:27015592 cg02565993 52210 −0.105 CLC 19:40228820 cg04764056 95048 −0.105 15:84974881 cg06813100 132909 −0.105 FBXO47 17:37123767 cg10600889 201304 −0.105 C14orf23; FOXG1 14:29240992 cg03472898 70248 −0.105 STK10 5:171541827 cg11334870 213456 −0.105 HLA- 6:33041697 cg00798281 16870 DPA1; HLA- DPB1 −0.105 P2RX5 17:3598755 cg13375828 246413 −0.105 LOC100506012; 19:46998383 cg06484000 126528 PNMAL2 −0.105 CMBL 5:10308785 cg26878318 468990 −0.105 MYO7A 11:76903134 cg24852442 435899 −0.105 DKFZp434L192 7:56555482 cg21720373 386268 −0.105 22:50482250 cg10146330 193299 −0.105 PKD1L2 16:81254209 cg07091758 138538 −0.104 2:75136334 cg12269972 229112 −0.104 6:30433749 cg07017214 137090 −0.104 SLC38A4 12:47226005 cg08005660 155507 −0.104 XPNPEP1 10:111683631 cg17201651 315167 −0.104 MYH11 16:15931580 cg03737209 75526 −0.104 FLOT1; TUBB 6:30696029 cg22024120 390747 −0.104 5:170763941 cg26497768 462323 −0.104 KCNK3 2:26916575 cg20955989 374545 −0.104 TRIM31 6:30080230 cg17048834 312621 −0.104 ABCA7; HMHA1 19:1064938 cg26576206 463804 −0.104 PRKCB 16:23850404 cg26562691 463553 −0.104 GAPDHS; LOC100506469; 19:36024313 cg25681177 449001 SBSN −0.104 CDSN; PSORS1C1; 6:31096204 cg03880216 78131 PSORS1C2 −0.104 MORC2; MORC2- 22:31316184 cg26278151 458506 AS1 −0.104 PCDHB5 5:140515736 cg15120855 280719 −0.104 6:68849256 cg09531389 182666 −0.104 WNT10A 2:219763642 cg16582803 304901 −0.104 14:56471704 cg05314124 105693 −0.104 MMRN2; SNCG 10:88717623 cg07436701 145067 −0.104 1:31280493 cg25204088 441555 −0.104 RFTN2 2:198540621 cg08373610 162365 −0.104 C1QTNF8 16:1152474 cg04004158 80525 −0.104 LOC100507463; 6:32805692 cg26685246 465648 PSMB8; TAP1; TAP2 −0.104 THOC2 X:122867073 cg08100265 157187 −0.104 PDLIM4 5:131589552 cg14815361 275561 −0.103 HHATL; KBTBD5 3:42727489 cg25129124 440393 −0.103 LOC84931 2:121223847 cg21406402 381501 −0.103 MACROD2 20:15177509 cg09937190 189621 −0.103 FAM163A 1:179713828 cg24460126 429325 −0.103 LOC100506012; 19:46988034 cg14128773 262082 PNMAL2 −0.103 ABHD8; DDA1; 19:17420304 cg10664184 202380 MRPL34 −0.103 SLC9A3 5:501938 cg22572362 398700 −0.103 C1QTNF8; LOC146336; 16:1133074 cg03327829 67387 SSTR5 −0.103 HCN4 15:73639105 cg11831431 221705 −0.103 3:27638612 cg14143723 262354 −0.103 BST2 19:17516712 cg01329005 27706 −0.103 4:115649889 cg14855679 276322 −0.103 TMEM136 11:120187999 cg09120934 175365 −0.103 IRS4 X:107980846 cg21111568 376933 −0.103 7:55072042 cg13490352 248855 −0.103 NCKAP5 2:134326172 cg18984282 343881 −0.103 NCR1 19:55417496 cg17804112 324505 −0.103 FHL3; SF3A3 1:38461687 cg17077180 313040 −0.102 SEMA5B 3:122712224 cg04830808 96325 −0.102 SLCO1B1 12:21324585 cg04579507 91754 −0.102 22:39323204 cg07123855 139180 −0.102 5:134881662 cg12613020 234541 −0.102 2:220352476 cg20456243 367005 −0.102 BAI1 8:143581070 cg25473866 445797 −0.102 PCDHB17; PCDHB6 5:140528785 cg26866168 468766 −0.102 GABBR2 9:101192792 cg14523238 270180 −0.102 5:74908170 cg00601450 12858 −0.102 OCA2 15:28053339 cg24943998 437498 −0.102 DPF1 19:38721070 cg23480284 413571 −0.102 TRAPPC12; TSSC1 2:3383257 cg12447832 231782 −0.102 FGF8; NPM3 10:103532798 cg16079364 296042 −0.102 CHRND; PRSS56 2:233384489 cg25571880 447246 −0.102 APCDD1 18:10456115 cg14623989 272309 −0.102 X:119151476 cg22956922 404868 −0.102 5:88991074 cg04117076 82698 −0.102 2:131010522 cg13302869 245147 −0.102 13:19243756 cg08628006 166844 −0.102 GCM2; SYCP2L 6:10881782 cg18187244 331085 −0.102 7:158243632 cg23859303 419493 −0.102 C16orf91; CCDC154 16:1478718 cg09615056 184112 −0.102 LRRC10B; MIR4488; 11:61273282 cg15263021 282930 SYT7 −0.102 FBXO7 22:32870150 cg21023126 375623 −0.102 13:112985463 cg17655970 322387 −0.102 15:74060182 cg26579616 463866 −0.102 6:28781594 cg00176718 3961 −0.102 PLK5 19:1542897 cg00392196 8275 −0.102 6:156983315 cg00269725 5770 −0.102 LOC100506776 7:38403507 cg05460050 108373 −0.102 5:15385947 cg00105403 2447 −0.102 CKMT1A 15:43984922 cg26247942 457947 −0.102 1:14462810 cg16164607 297377 −0.102 CDH22 20:44838981 cg07296387 142575 −0.102 10:133156015 cg09005971 173513 −0.101 CHRDL1 X:110038954 cg07653640 149177 −0.101 6:79339334 cg11074783 209107 −0.101 C1orf159 1:1052600 cg10126324 192906 −0.101 RINL; SIRT2 19:39360313 cg02711397 55211 −0.101 ZFP41 8:144339106 cg19504605 351705 −0.101 16:85981336 cg10274029 195601 −0.101 11:2212225 cg08241307 159919 −0.101 15:98196022 cg00744413 15733 −0.101 5:9119047 cg17608082 321764 −0.101 DPYSL5 2:27068081 cg08806184 169893 −0.101 GP6 19:55526208 cg27154418 473807 −0.101 C16orf61; CENPN 16:81039227 cg08265926 160397 −0.101 LOC100129620; 1:99471295 cg03593336 72666 LPPR5 −0.101 HLA- 6:33040610 cg20617328 369385 DPA1; HLA- DPB1 −0.101 CD3EAP; ERCC1; 19:45901453 cg08884571 369385 PPP1R13L −0.101 NALCN 13:102060580 cg22191606 393258 −0.101 MGLL 3:127473936 cg15694422 289708 −0.101 2:121279886 cg23405152 412432 −0.101 DNAH17; PGS1 17:76417995 cg22290140 394680 −0.101 PALM2; PALM2- 9:112593847 cg13893012 257062 AKAP2 −0.101 CHAT; SLC18A3 10:50816262 cg04730768 94454 −0.101 CCBL2; RBMXL1 1:89459658 cg23627354 415857 −0.101 21:10888524 cg19433175 350575 −0.101 WDSUB1 2:160142643 cg00168785 3783 −0.101 CYP26B1 2:72357937 cg15160709 281412 −0.101 6:74965323 cg11654562 218523 −0.101 AAAS; SP7 12:53715148 cg23032316 406156 −0.101 ZNF718 4:124693 cg15792688 291287 −0.101 11:120387302 cg06995068 136607 −0.101 7:147500722 cg17372101 317966 −0.101 2:3044737 cg11902863 222986 −0.101 14:77519601 cg13576669 250680 −0.101 PDE11A 2:178770927 cg04628174 92633 −0.101 CCDC64B; HCFC1R1; THOC6; 16:3079708 cg07868599 153015 TNFRSF12A −0.101 HLA- 6:33044510 cg00750366 15857 DPA1; HLA- DPB1 −0.101 ZNF767 7:149323101 cg08744726 168908 −0.100 LOC100506012; 19:46999224 cg11410682 214729 PNMAL2 −0.100 SDC3 1:31368797 cg00658151 13923 −0.100 CILP2; NDUFA13; 19:19643534 cg09935271 189575 YJEFN3 −0.100 HOXD3; LOC401022 2:177028804 cg10304824 196084 −0.100 PCDHGA1; PCDHGA10; PCDHGA11; PCDHGA12; PCDHGA2; 5:140807225 cg21929183 389472 PCDHGA3; PCDHGA4; PCDHGA5; PCDHGA6; PCDHGA7; PCDHGA8; PCDHGA9; PCDHGB1; PCDHGB2; PCDHGB3; PCDHGB4; PCDHGB5; PCDHGB6; PCDHGB7; PCDHGB8P −0.100 SCN7A 2:167350889 cg06038864 118973 −0.100 CEBPZ; LOC100505876; 2:37424015 cg23687288 417012 SULT6B1 −0.100 15:101389354 cg25878441 451879 0.100 20:690915 cg12338552 230066 0.100 KIRREL3- 11:126873181 cg08668551 167552 AS3 0.100 MLNR 13:49795541 cg06476591 126402 0.100 ZNF542 19:56879662 cg03146949 63935 0.100 KY 3:134369987 cg12307306 229684 0.100 TMEM200B 1:29449356 cg00866556 18256 0.100 ERICH1 8:687384 cg01200640 25242 0.100 HOXA5; HOXA6; 7:27187372 cg04265576 85698 HOXA7; LOC100133311 0.100 LOC386758; ZNF582 19:56904901 cg09568464 183339 0.100 ISM1 20:13200973 cg06262436 122823 0.100 10:100109635 cg23078268 407013 0.100 AQPEP 5:115298720 cg25044651 439130 0.100 AJAP1 1:4714672 cg12475759 232236 0.100 15:78112847 cg09369863 179831 0.100 HOXC4 12:54441509 cg10366797 197193 0.100 C7orf50; CYP2W1 7:1029594 cg22505411 397678 0.100 SLC22A3 6:160769116 cg07883823 153297 0.100 CDH8 16:62070086 cg06831576 133330 0.100 CCDC164; EPT1 2:26625047 cg13255216 244382 0.100 GHSR 3:172167445 cg04851268 96789 0.100 2:213402433 cg08042975 156156 0.100 TCHH 1:152081002 cg05523911 109583 0.100 ERBB2 17:37856378 cg26111030 455565 0.100 9:13278626 cg14655855 272946 0.100 EPGN; MTHFD2L 4:75174080 cg07643762 149031 0.100 ISL2; SCAPER 15:76634887 cg02245004 45800 0.100 UGGT2 13:96705123 cg08797194 169739 0.100 TBL1XR1 3:176827739 cg22160300 392814 0.100 LMO3 12:16762831 cg05355757 106496 0.101 17:25676440 cg07143451 139627 0.101 MYF5; MYF6 12:81110706 cg14067873 260821 0.101 EVX2; HOXD13 2:176948693 cg01749491 35793 0.101 OR7G3 19:9238958 cg03494634 70624 0.101 PON2; PON3 7:95025905 cg15927196 293537 0.101 TP73; WRAP73 1:3567986 cg24073122 423203 0.101 1:148854572 cg11818631 221440 0.101 ASCL2 11:2292000 cg13930892 257925 0.101 CNGB1 16:57915850 cg07029201 137333 0.101 HTR4 5:148033708 cg12825070 237836 0.101 C1orf201; NIPAL3 1:24741723 cg21298759 380184 0.101 7:158286570 cg23618588 415687 0.101 5:4942612 cg11468819 215620 0.101 5:56595244 cg19985056 359969 0.101 FLJ23152 6:17102678 cg05312353 105662 0.101 TCHH 1:152080543 cg04938315 98550 0.101 DCC 18:49868477 cg01839464 37773 0.101 FAM155A 13:108519752 cg06446668 125897 0.101 LOC285548; 4:13546151 cg27438798 478567 NKX3-2 0.101 6:29818300 cg22473097 397165 0.101 PSKH2 8:87082023 cg20982735 375026 0.101 UTP14A X:129065551 cg02699127 54944 0.101 FAM169A 5:74161231 cg07222505 141302 0.101 PLS1 3:142314493 cg00063773 1512 0.101 RUNX1T1 8:93115504 cg01806520 37028 0.101 2:133106819 cg12792250 237266 0.101 LOC654342 2:91848218 cg24829460 435500 0.101 5:2915236 cg21081803 376494 0.101 THRB 3:24536252 cg02333852 47654 0.101 SNAP91 6:84418789 cg16334314 300384 0.101 SGK1 6:134497247 cg03400131 68781 0.101 LOC729852; 7:7726202 cg26804611 467608 RPA3 0.101 ILF2; NPR1 1:153651568 cg04484579 89880 0.101 LOC643714; TOX3 16:52581551 cg02709321 55162 0.101 EYA4 6:133562475 cg20787173 372221 0.101 DBNDD2; PIGT 20:44035850 cg03172947 64447 0.101 PAK3 X:110187421 cg06455967 126034 0.101 HCN1 5:45695922 cg06498267 126802 0.101 ZIC4 3:147111120 cg27606499 481395 0.101 MAGI2-AS3 7:79082531 cg14592474 271684 0.101 WTIP 19:34972358 cg11869770 222476 0.101 UCP1 4:141490153 cg19346645 349167 0.101 COL23A1 5:178017853 cg26996818 471137 0.101 ZC3H12C 11:109964976 cg11758932 220367 0.101 SYT9 11:7273498 cg08185661 158874 0.101 8:41004167 cg09091657 174922 0.101 14:28733613 cg01840183 37791 0.101 CDK6 7:92442568 cg05278074 104986 0.101 FLJ42875; PRDM16 1:2990490 cg17001566 311833 0.102 7:53286906 cg10502121 199449 0.102 IQGAP3; TTC24 1:156542103 cg12262564 229022 0.102 DEAF1; DRD4 11:640606 cg20411756 366324 0.102 12:29303160 cg23787937 418459 0.102 FOXF1; LOC400550 16:86548895 cg08589354 166151 0.102 18:44787492 cg18074954 329008 0.102 KANK3 19:8398300 cg17490089 319937 0.102 PRDM12 9:133534961 cg13465477 248295 0.102 GLRA1 5:151304817 cg25352328 443801 0.102 GRIA2 4:158141570 cg00699993 14796 0.102 ADNP2; LOC100130522; 18:77905119 cg18973878 343754 PARD6G 0.102 TBL1X X:9432900 cg10839723 205305 0.102 LOC255480; TBX5 12:114845868 cg21907579 389107 0.102 TDRD5 1:179555658 cg17138852 314056 0.102 GPR176 15:40212781 cg17497271 320059 0.102 CHST3 10:73724697 cg19731268 355545 0.102 SNAP91 6:84418659 cg15950068 293877 0.102 PDXK 21:45147292 cg02253535 45973 0.102 5:168728149 cg15927720 293550 0.102 PRDM13 6:100061111 cg17302155 316788 0.102 DLL4 15:41219238 cg16069079 295915 0.102 PDGFRA 4:55100025 cg24799620 435038 0.102 FAM190A 4:91049007 cg17275700 316281 0.102 FUT9 6:96463959 cg25114913 440174 0.102 MOXD2P; PRSS58 7:141951023 cg12970830 240011 0.102 HPS4; SRRD 22:26875563 cg27087377 472647 0.102 17:25676386 cg05977781 117874 0.102 15:96905554 cg00221709 4765 0.102 RARRES1 3:158450208 cg03269060 66248 0.102 KDR 4:55991701 cg25722465 449597 0.102 SOX17 8:55370579 cg26059468 454690 0.102 14:95330880 cg18939596 343247 0.102 DLC1 8:13134166 cg20536983 368192 0.102 2:44312696 cg08613504 166550 0.102 ESR1 6:152085619 cg17741339 323560 0.102 CPLX2 5:175299035 cg06833732 133382 0.102 21:42218932 cg09880551 188645 0.102 CCDC108; CRYBA2; 2:219858146 cg24374738 427940 FEV; MIR375 0.102 FBXL15; NFKB2; 10:104170217 cg26089160 455163 PSD 0.102 PTPRZ1 7:121513695 cg10948929 206989 0.102 5:87979504 cg12991050 240324 0.102 RNF180 5:63461566 cg16485558 303034 0.102 ZDBF2 2:207140303 cg00410106 8675 0.103 CACNA1B 9:140917413 cg11827453 221623 0.103 CUL4B X:119694554 cg22267947 394373 0.103 DUOX1; DUOXA1 15:45422054 cg24505618 430070 0.103 RUNX1T1 8:93114294 cg07622493 148653 0.103 GBX2 2:237078733 cg07014673 137017 0.103 HOXD4; MIR10B 2:177014949 cg27160395 473893 0.103 GLRB 4:157997363 cg09688546 185354 0.103 DENND4C 9:19298547 cg19584733 353015 0.103 CASC4 15:44579510 cg00093643 2177 0.103 6:9399379 cg20876760 373416 0.103 GBX2 2:237076171 cg20804191 372465 0.103 LY6H 8:144240945 cg00831710 17537 0.103 6:28853021 cg24867279 436176 0.103 ALKBH7; CLPP 19:6362787 cg16848221 309550 0.103 5:1107837 cg22172143 393020 0.103 ZNF729 19:22469860 cg15413034 285081 0.103 TP73; WRAP73 1:3567412 cg16823083 309243 0.103 KBTBD11 8:1949342 cg25021970 438735 0.103 KLF16 19:1851995 cg11434705 215145 0.103 PEX5L 3:179670323 cg18765712 340436 0.103 NFIX 19:13107252 cg06197482 121707 0.103 2:9235972 cg04575202 91657 0.103 PCDHGA1; PCDHGA2 5:140712459 cg21722795 386305 0.103 1:32237923 cg04878000 97320 0.103 12:130422172 cg01448115 30160 0.103 RBFOX3 17:77454437 cg25258515 442358 0.103 EPB41L3 18:5543945 cg16304950 299805 0.103 13:112759355 cg15415452 285112 0.103 PPYR1 10:47083426 cg02394955 48953 0.103 ANKRD20A8P 2:95522902 cg08721908 168505 0.103 C2orf65 2:74813369 cg02102114 43172 0.103 MIR137; MIR2682 1:98519101 cg09896412 188935 0.103 NR1D1; THRA 17:38255871 cg09161455 176141 0.103 RPTOR 17:78815421 cg02363653 48276 0.103 LOC100505806; 5:9545976 cg11011938 208099 SNORD123 0.103 GRIN2A 16:10051500 cg06880615 134389 0.103 16:85369038 cg05877550 115832 0.103 CAPN1; SPDYC 11:64949878 cg25363789 444004 0.103 4:1407989 cg26860935 468675 0.103 THSD7A 7:11871690 cg26748945 466682 0.103 NEURL; SH3PXD2A 10:105344174 cg16311536 299928 0.103 FREM3 4:144621385 cg04514249 90444 0.103 CRNDE; IRX5 16:54965084 cg02056682 42152 0.104 POLR1B; TTL 2:113298655 cg12937159 239513 0.104 PRKD1 14:30396845 cg08608974 166464 0.104 LAIR1 19:54876795 cg20117742 361985 0.104 CNTNAP2 7:145814152 cg16254309 298913 0.104 CRMP1 4:5894930 cg15448975 285648 0.104 ASIP 20:32857151 cg09775533 186730 0.104 RBFOX1 16:6623787 cg04671611 93373 0.104 PCDHA1; PCDHA2; 5:140207609 cg16987900 311601 PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7 0.104 TGIF1 18:3452302 cg12899157 238913 0.104 ADRBK2 22:25961523 cg15154002 281307 0.104 FBP1 9:97402452 cg14211930 263861 0.104 GABRG2 5:161494500 cg08566437 165741 0.104 SMAD2 18:45458243 cg03294491 66702 0.104 SHISA6 17:11143830 cg08169394 158589 0.104 ADAMTSL3 15:84322946 cg14230666 264293 0.104 TRIM67 1:231296818 cg08855395 170825 0.104 RBP4 10:95361223 cg25793377 450725 0.104 EDIL3 5:83679941 cg07201620 140856 0.104 C10orf114; MIR1915 10:21789124 cg00580562 12369 0.104 CAMK1G 1:209759145 cg14034757 260152 0.104 NET1 10:5488500 cg14426660 268226 0.104 ACTL6B 7:100253914 cg08572611 165841 0.104 TEKT1 17:6734940 cg20663042 370096 0.104 LOC100271702 12:2030223 cg08621624 166700 0.104 OCRL X:128674222 cg27633753 481846 0.104 ANKRD53; TEX261 2:71205891 cg18006568 327816 0.104 RAB32 6:146864752 cg23833452 419083 0.104 NCAM1 11:112833773 cg12040830 225223 0.104 C3orf26; FILIP1L 3:99595145 cg22092811 391783 0.104 14:95331232 cg00814780 17210 0.104 LOC100507043 14:96342365 cg01718322 35254 0.104 CPLX1 4:789505 cg12792086 237263 0.104 LINC00327 13:24062873 cg08381620 162504 0.104 OLFM2 19:10024282 cg06911487 135026 0.104 FLJ41350; LBX1 10:102987257 cg12646649 235126 0.104 DUSP27 1:167090974 cg17801546 324462 0.104 PCDHA1; PCDHA10; 5:140346199 cg25500080 446199 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9; PCDHAC1; PCDHAC2 0.104 ABCC3; CACNA1G 17:48712370 cg00081975 1883 0.104 ZBTB16 11:113953621 cg20268992 364195 0.104 TMEM179 14:105070864 cg10281977 195739 0.104 ASB10; GBX1 7:150870036 cg12649727 235202 0.105 11:79151811 cg09673208 185113 0.105 CA10 17:50235965 cg22702328 400704 0.105 SOX17 8:55371013 cg08044097 156179 0.105 PIWIL1 12:130822603 cg24838063 435641 0.105 SLC7A14 3:170303721 cg21884231 388773 0.105 GRIN2D; GRWD1 19:48946564 cg04419610 88694 0.105 STK24 13:99218657 cg17176619 314752 0.105 FAM159B 5:63986733 cg14004073 259441 0.105 LOC728723; SNORA47; 5:76373719 cg03163459 64262 ZBED3 0.105 ZNF536 19:30866192 cg03758150 75925 0.105 PCDHA1; PCDHA10; 5:140346394 cg21537235 383480 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9; PCDHAC1; PCDHAC2 0.105 11:43569269 cg13201808 243496 0.105 GLDN 15:51634039 cg09495418 182011 0.105 UGGT1 2:128953231 cg11873311 222541 0.105 TBX3 12:115129446 cg10297792 195985 0.105 GPR123 10:134902278 cg07779444 151406 0.105 IRX1 5:3592435 cg19814981 357062 0.105 HOTAIRM1; HOXA1; 7:27142682 cg09871315 188506 HOXA2; HOXA3 0.105 PLK2 5:57756539 cg07479092 145902 0.105 TBX3 12:115123875 cg18573327 337428 0.105 ACTN2 1:236849994 cg20482698 367438 0.105 LOC388499; LRRC8E 19:7953281 cg27615578 481540 0.105 THRB 3:24536889 cg26146027 456200 0.105 GRIA2 4:158141542 cg10410142 197887 0.105 FN3K; FN3KRP 17:80693076 cg03077331 62673 0.105 OPA3; VASP 19:46032528 cg26958124 470450 0.105 HOXD1; LOC401022 2:177053274 cg03450948 69796 0.105 VWC2 7:49813088 cg01893212 38794 0.105 1:241520331 cg13849378 256225 0.105 DLX6-AS1 7:96622709 cg18502142 336304 0.105 4:180979631 cg12950911 239731 0.105 DNAH8 6:38683221 cg03166753 64319 0.105 NETO1 18:70536461 cg13644317 252077 0.105 FLJ12825; HOXC4 12:54454163 cg04024827 80948 0.105 6:125855124 cg02612397 53198 0.105 TP73; WRAP73 1:3567646 cg07382920 144177 0.105 4:165304540 cg21300373 380200 0.105 PRDM8 4:81118588 cg26299084 458882 0.106 ASIP 20:32857072 cg16655240 306231 0.106 TBX18 6:85474093 cg02106850 43270 0.106 THBD 20:23030250 cg09279949 178245 0.106 HOXD8; LOC100506783 2:177004015 cg18516557 336519 0.106 AQPEP 5:115298704 cg22010052 390518 0.106 WNT3A 1:228248013 cg26841013 468320 0.106 C14orf23; FOXG1 14:29236008 cg02681442 54626 0.106 COL4A1; COL4A2 13:110959428 cg06659727 129920 0.106 LOC100192378; 8:77590322 cg09938511 189649 ZFHX4 0.106 MAGI2-AS3 7:79083753 cg07448060 145248 0.106 CHRDL1 X:110039536 cg00619443 13187 0.106 FAM174B 15:93199037 cg25864024 451730 0.106 CNPY1 7:155301734 cg05944137 117184 0.106 PIGZ 3:196695320 cg23484358 413640 0.106 WNT7B 22:46372742 cg17179568 314808 0.106 TMPRSS3; UBASH3A 21:43824071 cg00134539 3054 0.106 EPHA5; LOC100144602 4:66534218 cg23193365 408770 0.106 DGKI 7:137125473 cg13734282 253993 0.106 UNC5C 4:96470286 cg11723848 219719 0.106 10:35256135 cg16738929 307860 0.106 NRG1 8:32504919 cg14663451 273089 0.106 HOTTIP; HOXA13 7:27246799 cg25720795 449560 0.106 LMF1; SOX8 16:1030619 cg05520409 109522 0.106 CRMP1 4:5894923 cg07963234 154775 0.106 HOTAIR; HOXC12; 12:54349169 cg26931862 469970 HOXC13 0.106 FOXI2 10:129535186 cg25539045 446751 0.106 1:41350014 cg13472192 248463 0.106 6:39740405 cg14173968 262984 0.106 20:690693 cg02217786 45276 0.106 PRSS3 9:33750687 cg14369648 267044 0.106 ZNF362 1:33721234 cg03767970 76126 0.106 FGFR1OP; MIR3939 6:167409842 cg02634327 53695 0.106 PCDH8 13:53419963 cg07847863 152703 0.106 HS6ST3 13:96742421 cg08612100 166526 0.106 ARMS2; HTRA1 10:124220367 cg09576143 183453 0.106 3:64430940 cg11236526 211855 0.106 CHST9 18:24765490 cg21895526 388922 0.106 C14orf132 14:96505722 cg16539629 304057 0.106 5:72596646 cg01050429 22138 0.106 8:61823275 cg06011086 118514 0.106 ST6GAL2 2:107502679 cg19412467 350247 0.106 CHAT; SLC18A3 10:50818299 cg11389172 214354 0.106 SLC6A1 3:11033866 cg00375819 7950 0.107 CLEC2L 7:139208852 cg08832906 170404 0.107 CCDC27; TP73- 1:3663435 cg10634619 201918 AS1 0.107 ZNF90 19:20188803 cg03317517 67181 0.107 GBP1 1:89523325 cg11083157 209272 0.107 OSR2 8:99961874 cg01581084 32753 0.107 KCNA7; NTF4 19:49575475 cg26923490 469807 0.107 ISL1 5:50678925 cg01587896 32872 0.107 NEFH 22:29876945 cg23353952 411659 0.107 7:149744935 cg15058253 279644 0.107 DDX25; HYLS1; 11:125774406 cg19792599 356708 PUS3 0.107 CBWD1; FOXD4 9:113530 cg01237333 25956 0.107 MIR1253 17:2659081 cg08457011 163741 0.107 TAS2R1 5:9623366 cg01984802 40719 0.107 TBX18 6:85474090 cg07028914 137326 0.107 ARL5C; CACNB1 17:37321631 cg20555674 368474 0.107 CNTNAP2 7:145813413 cg05749717 113523 0.107 2:165698949 cg21639287 385195 0.107 DNAJC6 1:65775570 cg26885220 469135 0.107 LILRA2 19:55084269 cg16893868 310220 0.107 CRNDE; IRX5 16:54965100 cg06191898 121610 0.107 PRKAR1B 7:751962 cg12441126 231659 0.107 ARHGEF10; 8:1772116 cg22880677 403671 MIR596 0.107 5:143978290 cg02030403 41637 0.107 CBLN4 20:54579084 cg01729827 35479 0.107 HOXD10; HOXD8; 2:176989349 cg09173768 176359 HOXD9 0.107 MIR196A1 17:46713962 cg13769834 254628 0.107 CRAMP1L 16:1665094 cg06810647 132860 0.107 ANGPT1 8:108511174 cg09443479 181117 0.107 DRD1 5:174871289 cg18190187 331134 0.107 1:227729906 cg11846112 221996 0.107 TGFBI 5:135364556 cg03625177 73315 0.107 TRMT2B X:100307142 cg11708328 219456 0.107 HOXD4; MIR10B 2:177014966 cg12215739 228288 0.107 X:39548267 cg11712793 219521 0.107 DEAF1; DRD4; 11:637035 cg23501406 413927 SCT 0.107 ZNF578 19:52956683 cg14582763 271490 0.107 KITLG 12:88974161 cg25741452 449928 0.107 BIRC5; TMEM235 17:76228233 cg09473315 181656 0.107 DMRTA2 1:50884480 cg10512745 199703 0.107 TMEM132C 12:128752040 cg04475027 89694 0.107 INPP5A; NKX6-2 10:134600675 cg15304699 283459 0.107 FGF8; MGEA5; 10:103536342 cg25209842 441648 NPM3 0.108 SLC22A20 11:64993335 cg23930334 420666 0.108 DIP2C 10:601816 cg06279296 123066 0.108 PRKD1 14:30396515 cg01588388 32879 0.108 EYA4 6:133562332 cg01328892 27704 0.108 PTPRM 18:7566781 cg16474170 302867 0.108 FAM129C 19:17650009 cg12585966 234024 0.108 CD247 1:167409054 cg06900257 134801 0.108 DRD5 4:9783206 cg04597433 92065 0.108 ISCA2; LTBP2 14:74959018 cg26195881 457091 0.108 HOXC4; HOXC5; 12:54408091 cg14569644 271205 HOXC6; HOXC8 0.108 FAM5C 1:190447290 cg23010538 405785 0.108 LRP12 8:105601696 cg00662122 14007 0.108 SFRP1 8:41166990 cg24319902 427005 0.108 13:24270087 cg10885151 205995 0.108 SVEP1 9:113341525 cg13606569 251311 0.108 3:181444563 cg04859466 96950 0.108 GABRA2 4:46391392 cg25145765 440699 0.108 KLF16 19:1851882 cg13382072 246526 0.108 CATSPER2P1; 15:44035561 cg15437748 285428 PDIA3 0.108 TRAF3IP2; TRAF3IP2- 6:111926749 cg15772366 291005 AS1 0.108 PCDHA1; PCDHA10; 5:140345966 cg04454086 89312 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9; PCDHAC1; PCDHAC2 0.108 VWC2 7:49813486 cg18206027 331413 0.108 6:157264715 cg16455339 302565 0.108 FAM110C 2:46465 cg14255256 264798 0.108 ZNF148 3:125076480 cg22895305 403903 0.108 ADAMTS16 5:5139874 cg16508480 303412 0.108 LOC100506757; X:133678716 cg19112977 345819 MGC16121; MIR424; MIR450A1; MIR450A2; MIR450B; MIR503; MIR542 0.108 SNX9 6:158243833 cg26845300 468408 0.108 TMEM181 6:158957433 cg00590036 12606 0.108 3:75661206 cg24573207 431170 0.108 PSKH2 8:87082014 cg04470072 89611 0.108 C10orf140; MLLT10 10:21814313 cg03891590 78352 0.108 MIR1258; ZNF385B 2:180726035 cg24575676 431204 0.108 UBD 6:29521501 cg20723129 371254 0.108 13:112759386 cg21054521 376149 0.108 NTNG2 9:135118406 cg14408447 267814 0.108 PTPRT 20:41818356 cg13168820 242965 0.109 SOX1 13:112722333 cg15466862 285977 0.109 RSPO1 1:38100467 cg13448605 247923 0.109 FGF8; MGEA5; 10:103536348 cg06169131 121199 NPM3 0.109 HOXB2; HOXB3 17:46618919 cg21780393 387140 0.109 SYT7 11:61335254 cg03200166 64948 0.109 SPATA18 4:52918471 cg17031543 312329 0.109 C3orf25; MBD4 3:129147397 cg17468185 319549 0.109 SRCIN1 17:36718549 cg20090283 361564 0.109 LOC400657 18:72263688 cg20276402 364322 0.109 C14orf23; FOXG1 14:29237480 cg16804284 308960 0.109 GABRG2 5:161494515 cg09220361 177083 0.109 8:72468820 cg24809973 435221 0.109 7:87974722 cg27221053 474880 0.109 NXPH2 2:139537745 cg10989763 207734 0.109 SGPL1 10:72594465 cg09140723 175742 0.109 FGF18 5:170848123 cg01392179 28917 0.109 ZNF300 5:150284796 cg21228005 379112 0.109 ZNF329; ZSCAN18 19:58629828 cg03145999 63909 0.109 LOC255480 12:114852091 cg01184975 24931 0.109 LPHN3 4:62383028 cg16225703 298417 0.109 7:156409058 cg16771407 308382 0.109 UNCX 7:1271236 cg18629009 338270 0.109 6:28945500 cg24126967 424128 0.109 MSX1 4:4860061 cg15092343 280260 0.109 SOX1 13:112721789 cg02547394 51873 0.109 CHST8 19:34112991 cg19594305 353222 0.109 BMP4 14:54413548 cg27302539 476206 0.109 FUT9 6:96463902 cg01758512 35982 0.109 2:240153778 cg25746499 450027 0.109 CCDC50; UTS2D 3:191047240 cg25235397 442049 0.109 PAX1 20:21686282 cg08448701 163575 0.110 UBQLN2 X:56589768 cg02587153 52704 0.110 10:13425015 cg18675735 338977 0.110 18:6414958 cg22058122 391310 0.110 CSMD1 8:4852036 cg12258042 228965 0.110 ASPG; MIR203; 14:104583067 cg23960324 421202 MIR3545 0.110 RACGAP1 12:50426901 cg19796532 356768 0.110 13:20875915 cg14472366 269103 0.110 14:95330984 cg19453488 350906 0.110 ZNF385D 3:21792857 cg26077378 454997 0.110 MBNL2 13:98002933 cg03372334 68296 0.110 ENO4 10:118608698 cg01035689 21828 0.110 CRHBP 5:76249502 cg04306063 86503 0.110 ODZ1 X:124097806 cg24761295 434425 0.110 6:78359965 cg10264012 195459 0.110 7:4921827 cg04816699 96082 0.110 MDGA1 6:37616598 cg03062252 62373 0.110 GJD2 15:35046760 cg21053529 376133 0.110 RLF; TMCO2; 1:40714009 cg06776907 132164 ZMPSTE24 0.110 HS3ST6 16:1968232 cg14936269 277598 0.110 DKFZp434J0226 19:46713473 cg21629821 385058 0.110 ANO1 11:69934109 cg05846633 115247 0.110 KIAA1755 20:36889364 cg14003035 259413 0.110 CORIN; NFXL1 4:47840011 cg26018901 454082 0.110 GLT1D1 12:129337897 cg04054313 81425 0.110 9:13279482 cg06202228 121794 0.110 CADM1 11:115069145 cg05125455 102021 0.110 DPYS 8:105479058 cg10303487 196069 0.110 KDM2B 12:122019080 cg17452615 319270 0.110 FOXI2 10:129535509 cg09614415 184092 0.110 ARHGEF4 2:131673894 cg12910906 239117 0.110 CPNE7 16:89654085 cg10499753 199387 0.110 CBLN1 16:49315302 cg08464190 163914 0.110 ADAM33; ATRN; 20:3641641 cg25164624 440992 GFRA4 0.110 LIMK2 22:31644160 cg15504662 286549 0.110 FLT3 13:28673762 cg26472910 461940 0.110 BANK1 4:102712397 cg14855874 276324 0.110 12:34500585 cg19457237 350958 0.110 KDM2B 12:122018897 cg09151742 175965 0.111 2:130763641 cg08857994 170896 0.111 PAX6 11:31819380 cg26029734 454240 0.111 HMGCLL1 6:55443868 cg06401021 125152 0.111 ZNF578 19:52956832 cg25763393 450297 0.111 TRPC4 13:38444134 cg15696906 289754 0.111 PLEKHA6 1:204256846 cg25407979 444757 0.111 C5orf38; IRX2 5:2743601 cg26195356 457077 0.111 EP400; PUS1 12:132433838 cg26147845 456245 0.111 MLLT3 9:20339790 cg21222426 379016 0.111 CTTNBP2 7:117513348 cg17112089 313639 0.111 EFHD1 2:233499460 cg06842071 133579 0.111 TMEM131 2:98613076 cg02995664 61036 0.111 DLX5; DLX6; DLX6- 7:96647021 cg23262036 410160 AS1 0.111 RAX 18:56940333 cg06676637 130191 0.111 COLEC12 18:500979 cg19461621 351026 0.111 MIR618 12:81331486 cg23441441 412989 0.111 7:64407743 cg24002887 421987 0.111 ST6GALNAC5 1:77334045 cg23243867 409762 0.111 MIR618 12:81331469 cg17061244 312814 0.111 LAMA1 18:7117680 cg07846220 152681 0.111 LOC100506012; 19:46975062 cg21988244 390260 PNMAL1 0.111 FGF12 3:192127330 cg16376000 301109 0.111 4:85403915 cg25174438 441100 0.111 GALR1 18:74961968 cg20872937 373368 0.111 LRIT1; RGR 10:86001254 cg14034858 260156 0.111 LAG3; PTMS 12:6888035 cg11429292 215067 0.111 PDE1C 7:32110523 cg14604568 271937 0.111 ZNF503; ZNF503- 10:77156218 cg20659435 370034 AS2 0.111 CDH8 16:62069337 cg02172312 44501 0.111 ISL1 5:50678913 cg17412886 318628 0.111 THRB 3:24537469 cg08123277 157665 0.111 HOXD10; HOXD11; 2:176972068 cg05500840 109127 HOXD12 0.111 ADAMTS16 5:5140003 cg03209854 65125 0.111 2:200524012 cg27211284 474729 0.111 SLC16A2 X:73641955 cg06805513 132754 0.111 HOXC4; HOXC5; 12:54424964 cg10005224 190710 HOXC6; MIR615 0.111 PTPRZ1 7:121513058 cg05931096 116896 0.111 SOX17 8:55370434 cg15186181 281779 0.112 ZNF536 19:30866194 cg06000994 118339 0.112 1:17199104 cg20168927 362799 0.112 STAC2 17:37381475 cg14328457 266291 0.112 CLMP 11:123008408 cg12995113 240381 0.112 CADPS 3:62860224 cg13514230 249338 0.112 TAPBPL; VAMP1 12:6572482 cg22129323 392333 0.112 13:112849184 cg20681688 370443 0.112 OR51A2; OR51A4 11:4977924 cg07589078 148007 0.112 11:110627909 cg04297660 86337 0.112 DNMT3A 2:25474327 cg10749994 203678 0.112 19:23185714 cg24911113 436942 0.112 CCT8L2; TPTEP1 22:17083482 cg00816224 17246 0.112 SLC35F3 1:234040781 cg09424759 180776 0.112 EPHB2; MIR4684 1:23038177 cg27573841 480859 0.112 HOXC8; HOXC9 12:54398518 cg08254359 160184 0.112 PRDM8 4:81118794 cg06307913 123528 0.112 22:33454324 cg05206884 103569 0.112 CR1L 1:207842927 cg20264068 364122 0.112 DNAAF2; LRR1; 14:50085410 cg24149364 424560 MGAT2; RPL36AL 0.112 MAPK14 6:36076933 cg20559215 368537 0.112 ISL2 15:76630209 cg23513966 414134 0.112 F10; PROZ 13:113807384 cg10067723 191777 0.112 C1orf229; ZNF124; 1:247275344 cg23695504 417170 ZNF669 0.112 HOOK1 1:60280809 cg23996071 421845 0.112 ZNF83 19:53142304 cg17132967 313971 0.112 TACR1 2:75292272 cg14054283 260559 0.112 15:29862568 cg13942157 258175 0.112 4:165305050 cg10453719 198622 0.112 SPAG6 10:22634218 cg12377139 230587 0.112 GRM6 5:178422071 cg23003783 405665 0.112 AQP12A; AQP12B 2:241623436 cg08049592 156267 0.112 16:15219673 cg04381865 87943 0.112 KIAA0182 16:85648263 cg07301329 142673 0.112 HOXC4; HOXC5; 12:54413384 cg15772924 291010 HOXC6; HOXC8 0.112 TCF15 20:591083 cg25984671 453527 0.112 C5orf38; IRX2 5:2751550 cg18371475 334040 0.113 ST6GAL2 2:107503672 cg21649258 385387 0.113 PTPRT 20:41818574 cg27625055 481684 0.113 PRKCG 19:54402455 cg02849693 57883 0.113 8:41754181 cg17331296 317296 0.113 SOX11 2:5836231 cg18897632 342660 0.113 17:55213656 cg11030264 208410 0.113 DPP6 7:153584597 cg14523847 270200 0.113 NLRP14; ZNF214 11:7041549 cg22867063 403403 0.113 6:28921805 cg22489957 397412 0.113 AMPD3; MIR4485; 11:10531596 cg18489034 336073 MTRNR2L8; RNF141 0.113 PALLD 4:169525923 cg24784416 434791 0.113 KHDRBS2 6:62996119 cg26715952 466174 0.113 PTGER2 14:52780158 cg21502048 382905 0.113 CTNNA2 2:79739863 cg08119884 157578 0.113 PRKAR1B 7:751833 cg00356183 7541 0.113 GPR125 4:22517094 cg08141192 158041 0.113 SLC6A17 1:110693237 cg11885396 222730 0.113 FAT1 4:187645120 cg27475132 479115 0.113 KIAA0748 12:55371892 cg24536818 430655 0.113 TRIM31 6:30071394 cg23642250 416154 0.113 DPP6 7:153584582 cg06495961 126761 0.113 8:142276422 cg25461290 445593 0.113 MRPS15; OSCP1 1:36912487 cg26030770 454254 0.113 EPPK1 8:144952929 cg18153977 330494 0.113 3:184231385 cg15718583 290162 0.113 HAND2; NBLA00301 4:174453166 cg15234400 282488 0.113 EGLN3 14:34420292 cg24665290 432653 0.113 HOXD1; LOC401022 2:177053297 cg19180624 346696 0.113 LINC00472 6:72130209 cg10039188 191305 0.113 DMRTA2 1:50886949 cg25191628 441334 0.113 KIT 4:55524199 cg10087973 192117 0.114 15:87892167 cg02693157 54811 0.114 NXPH1 7:8482235 cg12597389 234250 0.114 CACNG6; CACNG8; 19:54486058 cg02574502 52401 MIR935 0.114 HOXD11; HOXD12; 2:176964720 cg03964958 79739 HOXD13 0.114 7:127910927 cg08234689 159796 0.114 SPAG6 10:22634226 cg18247055 332095 0.114 FAM104B X:55187561 cg15824287 291790 0.114 FOXQ1 6:1313211 cg26422161 461072 0.114 11:91957992 cg07603330 148311 0.114 UTF1; VENTX 10:135050619 cg25577463 447348 0.114 ARL9; SRP72 4:57371607 cg06922635 135243 0.114 MACROD2; SEL1L2 20:13976143 cg06571075 128176 0.114 CNN3; LOC729970 1:95393096 cg18344652 333645 0.114 DUSP27 1:167090757 cg11236550 211856 0.114 MEGF6 1:3447348 cg17163527 314497 0.114 20:12809929 cg12505343 232775 0.114 CHST8 19:34112683 cg27058486 472166 0.114 PUS1; ULK1 12:132410932 cg24221398 425685 0.114 C14orf23; FOXG1 14:29244278 cg21195256 378436 0.114 1:88928467 cg02664812 54315 0.114 SLC44A2 19:10713016 cg05567294 110272 0.114 LOC100129794 14:37641462 cg25051529 439230 0.114 CRNDE; IRX5 16:54966471 cg16642791 305999 0.114 STAT3; STAT5A 17:40464780 cg25500196 446200 0.114 FGF18 5:170878209 cg02125316 43605 0.114 7:127775630 cg19871348 358070 0.114 7:158380884 cg22282410 394574 0.114 16:1048069 cg11978890 224277 0.114 RGAG4 X:71352048 cg03056321 62257 0.114 ZNF83 19:53142146 cg25793430 450728 0.114 FRYL; SLC10A4; 4:48492304 cg14249348 264663 ZAR1 0.115 HES6; LOC151174; 2:239140182 cg23497383 413854 LOC643387 0.115 6:28911938 cg25005112 438404 0.115 RBFOX1 16:6070188 cg08015447 155664 0.115 CHST8 19:34113214 cg06399302 125117 0.115 PRKG1 10:52752476 cg11175150 210715 0.115 CRNDE; IRX5 16:54965142 cg09641689 184540 0.115 EMX2; EMX2OS 10:119303225 cg15373239 284408 0.115 ATOH1 4:94749865 cg00335712 7088 0.115 DSC3 18:28622474 cg14719951 274021 0.115 IDH1; PIKFYVE 2:209128590 cg06177665 121341 0.115 CAMKK2; P2RX4 12:121678558 cg09297514 178526 0.115 GABRB3 15:27018037 cg18026588 328201 0.115 GNA15 19:3136430 cg01032675 21764 0.115 DPP6 7:153749736 cg18940047 343252 0.115 7:52156489 cg18793404 340916 0.115 KCNK18 10:118976677 cg27455890 478852 0.115 UPK3A 22:45680879 cg07021644 137193 0.115 SLC6A2 16:55689865 cg10362591 197113 0.115 4:104918078 cg05123845 101996 0.115 PON2; PON3 7:95025836 cg08828819 170325 0.115 PROX1 1:214160860 cg17954152 327012 0.115 THRB 3:24536562 cg24120841 424012 0.115 CDK5R2 2:219826870 cg27638196 481940 0.115 TMEM17 2:62732892 cg10848792 205426 0.115 RBFOX1 16:6533163 cg14642432 272661 0.115 PSMD14; TBR1 2:162270993 cg08184652 158859 0.115 FKBP5 6:35654363 cg03546163 71700 0.115 LOC100188947 10:93058376 cg17402294 318468 0.115 KIF26B 1:245820634 cg11424312 214996 0.115 ELAVL4 1:50513766 cg05697849 112668 0.115 KIAA0748 12:55376897 cg25486399 445985 0.115 VAX1 10:118896755 cg11398452 214514 0.115 RFX8 2:102091269 cg12291728 229438 0.115 6:28677112 cg14234426 264370 0.115 MTNR1A 4:187476455 cg25107254 440048 0.115 ID2 2:8817010 cg21946006 389750 0.115 HTR1A 5:63257847 cg09698471 185520 0.115 SORCS3 10:106401319 cg10778841 204179 0.116 14:74100987 cg14527456 270289 0.116 FLRT2 14:85996499 cg01711160 35095 0.116 SHANK1 19:51198381 cg07060551 137922 0.116 ALLC; COLEC11 2:3699195 cg13452994 248021 0.116 GRM6 5:178421711 cg12483476 232367 0.116 3:22413960 cg06062984 119382 0.116 LRRC36; TPPP3; 16:67427339 cg07355841 143680 ZDHHC1 0.116 HOTAIR; HOXC12 12:54355476 cg19188855 346817 0.116 TACSTD2 1:59042275 cg24851854 435890 0.116 NPY2R 4:156130016 cg21512644 383071 0.116 KIRREL3-AS3 11:126873379 cg00373707 7906 0.116 HS6ST3 13:96743087 cg27176138 474164 0.116 UBD 6:29521228 cg15814717 291599 0.116 CBWD2; FOXD4L1 2:114256781 cg10602757 201345 0.116 HES6; LOC151174; 2:239140024 cg13957874 258474 LOC643387 0.116 OPRK1 8:54164296 cg13405783 247011 0.116 NKX2- 14:36992233 cg04224064 84867 1; SFTA3 0.116 CCNA1 13:37005273 cg24297049 426624 0.116 2:91671535 cg02109405 43319 0.116 15:32607923 cg00943360 19827 0.116 PTPRG 3:61547130 cg09472360 181640 0.116 GLRB 4:157998201 cg10146199 193292 0.116 C1orf53; LHX9 1:197875080 cg12578211 233875 0.116 NPTX2 7:98246006 cg08315202 161360 0.116 GDF7 2:20871195 cg10553204 200490 0.116 8:61835848 cg06445016 125876 0.116 PRMT8 12:3600106 cg27316886 476555 0.116 ADAMTS16 5:5139878 cg04136610 83123 0.116 ZNF503; ZNF503- 10:77163383 cg18510056 336418 AS2 0.116 6:28911902 cg13293729 244984 0.116 DMRT1; DMRT3 9:971480 cg07173635 140295 0.116 6:170686343 cg01061164 22368 0.116 5:4942469 cg18101138 329470 0.116 FBN2 5:127874466 cg25532099 446652 0.116 PPM1L 3:160475090 cg04056576 81465 0.116 11-Mar 5:16179210 cg03705912 74857 0.116 SOX11 2:5837057 cg15989068 294511 0.116 INTU 4:128544255 cg16654911 306224 0.116 FAM20C 7:193262 cg08782337 169501 0.116 SLC15A3 11:60719947 cg26980692 470832 0.116 RBFOX1 16:6068835 cg19378133 349684 0.116 14:95826734 cg05162306 102773 0.116 SOX1 13:112717244 cg09469566 181584 0.117 PRPH 12:49689463 cg14029489 260043 0.117 MLXIPL 7:73038859 cg10092878 192247 0.117 ATP4A 19:36048943 cg19715414 355233 0.117 MANEAL; YRDC 1:38261057 cg24433287 428889 0.117 KCNA4 11:30038677 cg15310492 283522 0.117 3:54119792 cg03494612 70623 0.117 MMP17 12:132312461 cg03570417 72216 0.117 ADAT1; KARS 16:75661691 cg01921773 39352 0.117 FIGLA 2:71017541 cg22650617 399823 0.117 CNPY1 7:155324691 cg09090582 174907 0.117 BDNF 11:27740876 cg05733135 113285 0.117 LINC00467 1:211590292 cg20802616 372441 0.117 OXTR 3:8813493 cg08449558 163593 0.117 DNAJB13 11:73668626 cg20737388 371474 0.117 SLC34A2 4:25657365 cg19766441 356236 0.117 LINC00461; MIR9-2 5:87968528 cg14636534 272541 0.117 PIWIL1 12:130822286 cg13861644 256478 0.117 DSC3 18:28622593 cg15439862 285459 0.117 UBD 6:29521046 cg18342026 333604 0.117 GABRA2 4:46391929 cg23160016 408245 0.117 DUSP8; MOB2 11:1575607 cg05280206 105032 0.117 PHACTR2 6:143998958 cg26846959 468429 0.117 FAM47E; SCARB2 4:77134471 cg19050061 344935 0.117 SPG7 16:89600764 cg08905080 171867 0.117 BBX 3:107244746 cg02321062 47394 0.117 ALDH1L1 3:125899370 cg01566526 32429 0.117 3:4856199 cg08998950 173407 0.117 LTBP3 11:65325158 cg08965235 172854 0.118 16:85203635 cg00942219 19808 0.118 PIPOX 17:27369780 cg06144905 120806 0.118 LMNB2 19:2446487 cg18087306 329215 0.118 GUSBP4 6:58263193 cg17976157 327360 0.118 ISL1 5:50679149 cg08734740 168746 0.118 BAALC; C8orf56 8:104153627 cg18168101 330737 0.118 1:65534742 cg20301308 364692 0.118 9:136474735 cg03262554 66122 0.118 ZC3H8 2:113012627 cg27242549 475215 0.118 ZNF148 3:125076233 cg12508343 232821 0.118 MGC45800 4:183064388 cg00053393 1279 0.118 NRG2; PSD2 5:139223811 cg08682153 167769 0.118 HOXA5; HOXA6; 7:27187269 cg06237983 122446 HOXA7; LOC100133311 0.118 CADPS 3:62861055 cg15957055 293976 0.118 KCNQ1DN 11:2891082 cg25203481 441543 0.118 ZFPM2 8:106332119 cg10868817 205750 0.118 3:171543413 cg11639615 218225 0.118 PXDN 2:1748112 cg12164282 227454 0.118 TIGD7; ZNF75A 16:3355553 cg05540369 109851 0.118 SP8 7:20824770 cg27618240 481572 0.118 15:96905729 cg11157253 210450 0.118 ADRA1D 20:4202378 cg04293085 86242 0.118 LOC100130298 8:61880392 cg04882213 97419 0.118 DYNLT1; SYTL3 6:159068210 cg27278961 475791 0.118 PCDHA1; PCDHA2; 5:140201656 cg11781306 220669 PCDHA3; PCDHA4; PCDHA5; PCDHA6 0.119 DPP6 7:153584416 cg22620221 399362 0.119 ZNF468 19:53361164 cg08531263 165137 0.119 CNTNAP5 2:124782831 cg08790440 169635 0.119 FBN2 5:127873106 cg17564775 321142 0.119 CDH8 16:62070184 cg01718742 35267 0.119 COX19; CYP2W1 7:1018969 cg01823585 37440 0.119 LPHN2 1:82267931 cg02243785 45777 0.119 LOC100130155; 8:65290484 cg07792478 151647 MIR124-2 0.119 LHX8 1:75595970 cg22694818 400568 0.119 LOC339529; ZNF238 1:244213616 cg19698993 354930 0.119 OLFML2A 9:127531952 cg14046477 260419 0.119 EPHA1; LOC285965 7:143108841 cg16618979 305561 0.119 AZU1; LPPR3; 19:822086 cg21928701 389466 MIR3187 0.119 OSBPL3 7:25005464 cg07110009 138907 0.119 7:52155829 cg11342198 213584 0.119 PREX2 8:68864769 cg06617456 128991 0.119 CHRNA4 20:61992494 cg01743841 35695 0.119 ISLR2; LOC283731 15:74425552 cg01178680 24810 0.119 UNC5D 8:35092823 cg08000065 155421 0.119 PRKAR1B 7:751830 cg27331241 476807 0.119 MAP7 6:136847359 cg18421949 334865 0.119 EPHA6 3:96533511 cg11410023 214721 0.119 HOXA5; HOXA6; 7:27188364 cg19816811 357110 HOXA7; LOC100133311 0.119 PDGFC 4:157892765 cg22451233 396868 0.119 HCG4B 6:29895005 cg01519225 31476 0.119 ATP2C2 16:84402160 cg08974450 173017 0.119 4:187037318 cg05379002 107021 0.119 TRIM71 3:32860178 cg12338417 230063 0.119 POU6F2 7:39125198 cg02367316 48362 0.119 RBP1 3:139258295 cg12497564 232636 0.119 EFS; IL25 14:23834909 cg13011388 240610 0.119 MYRIP 3:39851788 cg07892785 153449 0.119 RAB38 11:87908783 cg01568784 32481 0.119 TBX4 17:59532306 cg14823851 275680 0.119 TOX2 20:42544794 cg03011535 61343 0.120 DLC1 8:13134144 cg03304380 66890 0.120 SNED1 2:241938436 cg08233654 159775 0.120 KIF25 6:168436019 cg12003941 224653 0.120 C1orf35; MRPL55 1:228297864 cg22163199 392875 0.120 CTNNA2 2:79739278 cg18806140 341143 0.120 ALOX5 10:45869702 cg27243389 475225 0.120 NAALAD2 11:89867976 cg21500966 382886 0.120 NLRP2 19:55477755 cg17760849 323892 0.120 AIM1 6:106957995 cg20796467 372352 0.120 ZFPM2 8:106331995 cg15449956 285663 0.120 ISL1 5:50679290 cg11711420 219504 0.120 C3orf15 3:119422161 cg08145590 158129 0.120 4:82965250 cg04643822 92882 0.120 FGFR1 8:38323059 cg13278539 244735 0.120 SRRM4 12:119591747 cg27010159 471336 0.120 UGP2 2:64069682 cg19915305 358803 0.120 GLI4 8:144361073 cg11240062 211921 0.120 TOX2 20:42544792 cg13459498 248157 0.120 AQP4; CHST9- 18:24445692 cg12445775 231741 AS1 0.120 NKX6-1 4:85418265 cg12076463 225925 0.121 PCDHGA12; PCDHGC3; 5:140871385 cg24619378 431928 PCDHGC4; PCDHGC5 0.121 HOXA10; HOXA10- 7:27204894 cg27009703 471328 HOXA9; HOXA7; HOXA9; LOC100133311; MIR196B 0.121 DLG5 10:79622515 cg11063088 208886 0.121 KDM2B 12:122019076 cg15234492 282489 0.121 IRF6 1:209979733 cg21951975 389837 0.121 ACTL6B 7:100254149 cg16024950 295200 0.121 ONECUT2 18:55095177 cg05735180 113314 0.121 WDR17 4:176987020 cg08095852 157102 0.121 CLEC14A 14:38725312 cg08139247 158007 0.121 HOXD4; MIR10B 2:177014555 cg19519747 352000 0.121 UTRN 6:144608500 cg15785898 291201 0.121 MFSD7; MYL5 4:682834 cg24693053 433212 0.121 GABRA5 15:27112430 cg10652393 202197 0.121 PLSCR2 3:146187706 cg02128651 43681 0.121 PENK 8:57358590 cg21694941 385984 0.121 FBN2 5:127873283 cg05209584 103634 0.121 PAX1 20:21686293 cg01783070 36501 0.121 18:6414602 cg08336641 161747 0.121 NRG1 8:31497464 cg24946597 437530 0.121 FBXO39; XAF1 17:6679564 cg02374745 48515 0.121 WNT2 7:116963259 cg07697895 149945 0.121 8:142413013 cg06830360 133304 0.121 SNORA76; SNORD104; 17:62222808 cg20969675 374778 TEX2 0.121 EHBP1; LOC100132215; 2:63275602 cg27344587 477023 OTX1 0.121 IRX1 5:3599686 cg01294808 27051 0.121 CADM2 3:85008587 cg13331200 245621 0.121 FAT1 4:187647690 cg12769506 236972 0.121 10:131762052 cg11757357 220344 0.122 ADAM12 10:128077307 cg05237641 104212 0.122 CLVS2 6:123317569 cg08194879 159033 0.122 12:127940654 cg16065021 295854 0.122 SLC6A3 5:1446208 cg14502484 269687 0.122 ASPG; MIR203; 14:104583071 cg03401997 68837 MIR3545 0.122 CCDC146 7:76747831 cg02901065 58990 0.122 ZFP42 4:188916581 cg15718581 290161 0.122 2:225306901 cg10193763 194181 0.122 HOXD10; HOXD11; 2:176972581 cg24633978 432153 HOXD12 0.122 ENTPD6 20:25177340 cg00926318 19472 0.122 TSHZ1; ZADH2 18:72917387 cg22088248 391726 0.122 POLG 15:89879190 cg24365117 427793 0.122 7:43291318 cg02964324 60381 0.122 NETO1 18:70534298 cg23883696 419843 0.122 POU4F1 13:79170283 cg24221648 425692 0.122 GNAS; GNAS- 20:57427650 cg02890368 58752 AS1 0.122 PDE2A 11:72301724 cg26268145 458304 0.122 ARL9; SRP72 4:57372356 cg14775423 274866 0.122 HLCS 21:38353114 cg22777062 401811 0.122 TP73; WRAP73 1:3568210 cg20677901 370380 0.122 2:190192866 cg25550823 446916 0.122 SNX31 8:101661788 cg10715223 203178 0.122 ARHGEF10; MIR596 8:1771973 cg10964367 207265 0.122 B3GNT4; DIABLO; 12:122688787 cg23445859 413050 LRRC43 0.122 TRPC4 13:38444227 cg16409955 301745 0.122 KCNA1 12:5020693 cg08832227 170388 0.122 EXT2 11:44118094 cg24662154 432585 0.123 ADAMTSL3 15:84363061 cg14598478 271807 0.123 STK32B 4:5053504 cg08323075 161506 0.123 DKFZp434J0226 19:46713446 cg21100328 376752 0.123 RNF180 5:63461803 cg09839635 187877 0.123 CYB561D2; NPRL2; 3:50383175 cg00460268 9723 RASSF1; TMEM115; ZMYND10 0.123 RNF207; RPL22 1:6269448 cg25286333 442745 0.123 17:2627661 cg12187586 227838 0.123 P2RY12 3:151058783 cg13229867 243994 0.123 DUSP4 8:29210592 cg05128656 102084 0.123 HTR4 5:148034045 cg04091563 82145 0.123 TMEM164 X:109246494 cg04926827 98346 0.123 C1QL1 17:43044660 cg24042242 422692 0.123 PCDHGA1; PCDHGA2 5:140711852 cg05580809 110540 0.123 VSTM5 11:93583693 cg14291919 265581 0.123 ZFP2; ZNF454 5:178367827 cg24843380 435721 0.123 KLHDC10 7:129781152 cg07026433 137279 0.123 SLIT2 4:20257590 cg19940312 359283 0.123 IRF6 1:209979665 cg22029157 390830 0.123 11:71350975 cg13009111 240573 0.123 PITX1 5:134367394 cg23064601 406786 0.123 PLSCR2 3:146187740 cg21569635 384039 0.124 SKAP2 7:26897685 cg03730533 75381 0.124 CABYR; TTC39C 18:21719433 cg26349976 459840 0.124 TSHZ1; ZADH2 18:72916776 cg02750262 56023 0.124 ZNF835 19:57183118 cg08146323 158144 0.124 TBX15 1:119535928 cg24035245 422569 0.124 OSGIN1 16:83986941 cg07978099 155051 0.124 PRKD1 14:30396444 cg10501704 199443 0.124 SCRT2 20:644758 cg12590600 234112 0.124 TRPM4 19:49713828 cg10951975 207052 0.124 5:53564 cg22807585 402379 0.124 DUOX2; DUOXA1; 15:45405103 cg04222582 84830 DUOXA2 0.124 14:99584667 cg23683254 416925 0.124 FEZF1; LOC154860 7:121940216 cg27393010 477821 0.124 NELF; PNPLA7 9:140348828 cg14384158 267359 0.124 PTPN13 4:87515467 cg15543566 287079 0.124 KCTD14; NDUFC2- 11:77734206 cg16769152 308350 KCTD14 0.124 GBX2 2:237076811 cg21426003 381745 0.124 PON2; PON3 7:95025829 cg08520743 164919 0.124 CPEB1 15:83316223 cg27578811 480950 0.124 NTM 11:131780492 cg15617814 288391 0.124 ATP9A 20:50385371 cg01900832 38931 0.124 13:36705475 cg25724283 449620 0.124 10:21462441 cg17426273 318854 0.124 ALX1 12:85674296 cg07780095 151415 0.124 6:106441441 cg03942932 79300 0.125 HECW1 7:43152254 cg08039116 156084 0.125 8:61823027 cg20904475 373766 0.125 PRDM8 4:81118188 cg03463411 70030 0.125 INSR 19:7294093 cg26532951 462966 0.125 HOXD4; MIR10B 2:177014959 cg17104824 313519 0.125 PON2; PON3 7:95025740 cg23230584 409500 0.125 TFAP4 16:4324280 cg00021532 522 0.125 CRNDE; IRX5 16:54965087 cg05870072 115671 0.125 14:103673450 cg26579556 463863 0.125 NXPH2 2:139537824 cg18150439 330428 0.125 13:42002627 cg25532201 446653 0.125 KLHL4 X:86772364 cg15554694 287280 0.125 MALL; NPHP1 2:110873396 cg01615704 33421 0.125 HAAO 2:43020264 cg17246140 315873 0.125 DPP6 7:153584609 cg27032232 471703 0.125 LHFPL4 3:9594385 cg04061117 81564 0.125 EGFL7 9:139551542 cg13900767 257221 0.125 COX16; SYNJ2BP; 14:70827109 cg13099429 241974 SYNJ2BP- COX16 0.125 LHX6 9:124990456 cg13817952 255647 0.125 KCNK16; KCNK17 6:39281885 cg08315770 161367 0.125 CCT8L2; TPTEP1 22:17082770 cg14505585 269757 0.125 FAM135B 8:139509672 cg23294090 410690 0.125 GDA 9:74764428 cg21170041 377969 0.126 IL1RAPL1 X:28604661 cg06927864 135328 0.126 CIDEA 18:12254551 cg07204280 140912 0.126 NPAS3 14:33403862 cg08117309 157524 0.126 ENPP2 8:120650994 cg02534163 51618 0.126 7:156400711 cg16561657 304460 0.126 STXBP5L 3:120627406 cg05293820 105268 0.126 CNTN1 12:41086680 cg14625113 272330 0.126 IRF6 1:209979283 cg25192855 441351 0.126 CAST 5:96038614 cg24742349 434137 0.126 FBN2 5:127874463 cg11965976 224052 0.126 ATXN2 12:112035212 cg08273772 160571 0.126 PDE4D 5:59189120 cg03323696 67297 0.126 TOX2 20:42544663 cg06779449 132219 0.126 BCOR X:40005177 cg12737514 236481 0.126 KIAA1530 4:1366597 cg23921777 420508 0.126 CXCL2 4:74965262 cg23244559 409786 0.126 MIR1469; NR2F2 15:96884187 cg07016184 137060 0.126 EGLN2; RAB4B- 19:41319790 cg01282508 26784 EGLN2 0.126 TMEM132C 12:128751460 cg03530754 71358 0.126 PDZRN4 12:41582349 cg21926708 389441 0.126 EFCAB1 8:49647734 cg08258526 160240 0.126 PIN4 X:71401384 cg23905908 420234 0.126 RP11- 1:111813690 cg07197785 140790 165H20.1 0.126 LOC645249 7:156814491 cg00024086 585 0.126 ATHL1; IFITM5; 11:288305 cg08829299 170335 NLRP6 0.126 GALR1 18:74961966 cg03659519 73996 0.126 1:2738746 cg10105681 192507 0.126 RGAG4 X:71351980 cg20347665 365414 0.126 RNF180 5:63461574 cg14591786 271667 0.127 EOMES 3:27772805 cg11642106 218279 0.127 HOXB9; MIR196A1 17:46711017 cg23690166 417069 0.127 ARMC5; TGFB1I1 16:31484032 cg10995380 207836 0.127 PON2; PON3 7:95025855 cg04685170 93636 0.127 PRSS3 9:33749216 cg22410499 396383 0.127 CPNE4 3:131246097 cg08151596 158229 0.127 GABRG3 15:27216529 cg11651237 218458 0.127 B4GALNT2 17:47209827 cg20233029 363633 0.127 MSX1 4:4864488 cg21538208 383498 0.127 ARHGEF4 2:131673771 cg09015973 173696 0.127 PCDHA1; PCDHA10; 5:140261663 cg02051771 42046 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9 0.127 ASPG; MIR203; 14:104583048 cg13673833 252679 MIR3545 0.127 MAGI2-AS3 7:79083507 cg02523844 51402 0.127 IRX2 5:2739602 cg21573200 384101 0.127 NUP210 3:13431720 cg17336044 317388 0.128 2:132088801 cg14001664 259383 0.128 CCDC130; MRI1 19:13875137 cg14272688 265161 0.128 2:71115370 cg10954469 207096 0.128 ZNF347; ZNF415 19:53635967 cg18301583 332927 0.128 SNED1 2:241938321 cg21384492 381197 0.128 VSTM2A 7:54614477 cg06584494 128412 0.128 MEIS2 15:37388540 cg00691830 14602 0.128 NLRP14; ZNF214 11:7041930 cg17228942 315646 0.128 KCNV1 8:110988043 cg23291534 410667 0.128 MAGI2-AS3 7:79081666 cg06809544 132847 0.128 FBXO39; XAF1 17:6679348 cg00376544 7966 0.128 PTF1A 10:23481176 cg22746058 401390 0.128 TAL1 1:47691160 cg10810752 204761 0.128 FBRSL1 12:133137479 cg03621470 73255 0.128 CCDC36; LOC646498 3:49236946 cg03540175 71588 0.128 CXXC4 4:105412800 cg22604213 399113 0.128 MSX1 4:4864902 cg11078084 209175 0.128 FLJ45983; GATA3 10:8097641 cg17124583 313810 0.128 ADRA1B 5:159343549 cg07011172 136949 0.128 UBD 6:29521272 cg22762215 401614 0.128 TGFBI 5:135364568 cg15146621 281189 0.128 CHST8 19:34112825 cg26565021 463587 0.128 JPH1 8:75234269 cg23599843 415405 0.128 ACSS1 20:25039707 cg03321508 67252 0.128 BASP1; LOC285696 5:17218778 cg14306451 265851 0.128 11:79148502 cg05454619 108297 0.128 NLRP14; ZNF214 11:7041752 cg11838299 221836 0.128 2:9235898 cg20610452 369302 0.129 PCDHA1; PCDHA10; 5:140346236 cg12832313 237924 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9; PCDHAC1; PCDHAC2 0.129 C8orf42 8:495736 cg05142982 102391 0.129 11:70962935 cg11263364 212293 0.129 CDH12 5:21751337 cg23404351 412413 0.129 LOC100507055; 12:133195094 cg00058329 1387 P2RX2; POLE 0.129 CCDC164; EPT1 2:26624934 cg14273450 265175 0.129 ISM1 20:13200929 cg22588144 398900 0.129 EGR2 10:64578919 cg22903908 404041 0.129 GSDMD; ZC3H3 8:144626190 cg09422696 180737 0.129 KCNK9 8:140715802 cg21415530 381621 0.129 3:94243571 cg16274205 299307 0.129 UNC80 2:210636539 cg24938830 437420 0.129 CABLES2; RPS21 20:60958108 cg14168305 262866 0.129 11:124324477 cg03252499 65933 0.129 FAT1 4:187645144 cg24410535 428521 0.129 PPP1R14A; SPINT2 19:38747378 cg02571816 52340 0.130 ASIP 20:32856898 cg05267394 104806 0.130 CCDC144A 17:16593885 cg02879122 58511 0.130 CRISPLD1 8:75896720 cg15953602 293925 0.130 KAL1 X:8700172 cg18396832 334461 0.130 CELF1 11:47528955 cg13308137 245225 0.130 HOXC4; HOXC5; 12:54404315 cg13545297 249972 HOXC6; HOXC8; HOXC9 0.130 DOCK1; FAM196A 10:128994608 cg25984344 453521 0.130 LOC100507266 4:4577273 cg07914772 153870 0.130 KCNS2 8:99440279 cg14486338 269395 0.130 5:3093070 cg20428720 366575 0.130 HOXA10; HOXA10- 7:27204981 cg26521404 462738 HOXA9; HOXA7; HOXA9; LOC100133311; MIR196B 0.130 RNF180 5:63461582 cg06776999 132168 0.130 MTRNR2L4; OR2C1 16:3415077 cg09999114 190605 0.130 PENK 8:57358312 cg12877723 238608 0.130 NETO1 18:70534767 cg18448581 335334 0.130 TTC40 10:134650467 cg25403174 444670 0.130 ASXL3 18:31158234 cg24880056 436440 0.130 DEAF1; DRD4; 11:637038 cg15861585 292487 SCT 0.130 GLT1D1 12:129337910 cg06419750 125449 0.130 LOC643714; TOX3 16:52580987 cg26817217 467846 0.131 UNCX 7:1265851 cg15591276 287897 0.131 RARRES1 3:158450251 cg14226182 264214 0.131 PRDM8 4:81118500 cg19409579 350194 0.131 DQX1; PCGF1; 2:74742786 cg19656282 354267 TLX2 0.131 STL 6:125283245 cg24822696 435377 0.131 CPNE4 3:131756545 cg12981577 240178 0.131 UBD 6:29521407 cg03402459 68848 0.131 HLCS 21:38362725 cg14785464 275096 0.131 SHROOM2 X:9753940 cg26318441 459244 0.131 FTSJ2; NUDT1; 7:2289054 cg17467898 319545 SNX8 0.131 PCDHB10; PCDHB16; 5:140562738 cg21081817 376495 PCDHB7; PCDHB8; PCDHB9 0.131 NOS1 12:117798954 cg04883903 97454 0.131 CHL1 3:238615 cg07746943 150879 0.131 SGPP2 2:223289277 cg00043095 1074 0.131 TUSC1 9:25678015 cg13985784 259065 0.131 NKX2-8 14:37051417 cg10530851 200070 0.132 FRYL; SLC10A4; 4:48492225 cg22773661 401769 ZAR1 0.132 LOC402160; RNF4 4:2464050 cg21722242 386297 0.132 CHL1 3:239207 cg21145524 377484 0.132 18:73167671 cg12975230 240067 0.132 SALL1 16:51188697 cg00683332 14419 0.132 FAM19A5 22:48972349 cg06273376 122999 0.132 GRM6 5:178422128 cg00582971 12427 0.132 RTBDN 19:12936512 cg07583894 147890 0.132 HOXA10- 7:27192656 cg23263937 410186 HOXA9; HOXA5; HOXA6; HOXA7; HOXA9; LOC100133311 0.132 TMEM45B 11:129685751 cg27274706 475714 0.132 NRK X:105066526 cg07674139 149532 0.132 NRG1 8:31497829 cg26267340 458285 0.132 NAALAD2 11:89867653 cg01577414 32669 0.132 SMTNL2 17:4488345 cg07888347 153363 0.132 CHRNB1; FGF11; 17:7341641 cg25563256 447126 TMEM102 0.132 NEFM 8:24771326 cg07552803 147256 0.132 HMGCLL1 6:55443757 cg11907729 223067 0.132 WNT2B 1:113051846 cg27181253 474270 0.132 RADIL 7:4869981 cg00469380 9930 0.132 NRXN1 2:50574196 cg14875171 276641 0.133 CTNNA2 2:79740208 cg04670857 93356 0.133 DOCK1; FAM196A 10:128994605 cg12204732 228111 0.133 12:132146956 cg24533007 430572 0.133 CBLN2 18:70209432 cg13478228 248599 0.133 PIEZO2 18:11149470 cg03686593 74481 0.133 NELL1 11:20690957 cg17371081 317950 0.133 SLC34A2 4:25657381 cg03738352 75550 0.133 3:74663796 cg00735667 15563 0.133 5:132947501 cg23236554 409620 0.133 LRRC4C 11:40315392 cg17949440 326949 0.133 CHST9 18:24765485 cg16933181 310893 0.133 6:168147405 cg07147204 139710 0.134 CNTNAP2 7:145813417 cg11592503 217489 0.134 ENTPD2; NPDC1 9:139943146 cg14024893 259944 0.134 MAGI2-AS3 7:79083445 cg04652097 93018 0.134 TACR3 4:104640662 cg18538958 336883 0.134 NXNL2 9:91150537 cg14347199 266666 0.134 COX6B2; FAM71E2; 19:55866087 cg20106459 361820 IL11; SUV420H2 0.134 DPRXP4; RNF135 17:29297391 cg01347228 28034 0.134 GPR6 6:110300573 cg26252167 458027 0.134 MAN1C1 1:25944514 cg10706230 203035 0.135 TJP1 15:30114474 cg19965221 359674 0.135 SSPO 7:149484798 cg16516272 303562 0.135 C3orf25; MBD4 3:129147541 cg14779951 274962 0.135 13:50701501 cg23104954 407495 0.135 LRP3 19:33685817 cg10276227 195631 0.135 HOXD10; HOXD8; 2:176994448 cg14473102 269120 HOXD9; LOC100506783 0.135 SNAP91 6:84418433 cg24190603 425243 0.135 ISL1 5:50679147 cg16318053 300061 0.135 PCDHA1; PCDHA10; 5:140261653 cg19876814 358160 PCDHA11; PCDHA12; PCDHA13; PCDHA2; PCDHA3; PCDHA4; PCDHA5; PCDHA6; PCDHA7; PCDHA8; PCDHA9 0.135 SSTR1 14:38678420 cg18443253 335246 0.136 KCNQ4 1:41248881 cg16294363 299640 0.136 DUSP27 1:167090646 cg17104258 313508 0.136 4:170696239 cg18912209 342859 0.136 CXCL5 4:74864165 cg27109129 473022 0.136 LHX8 1:75602412 cg08146483 158147 0.136 CCR6 6:167559913 cg16338365 300452 0.136 KIF17; SH2D5 1:21044101 cg09793172 187028 0.136 ANKRD26P3; 13:19918586 cg06722407 131065 LINC00421 0.136 ZFP42 4:188916875 cg10242602 195098 0.136 UBD 6:29521430 cg15818307 291669 0.136 HOXD1; LOC401022 2:177053292 cg05099387 101608 0.136 ISM1 20:13200944 cg14060111 260677 0.136 NMBR 6:142409507 cg20747266 371647 0.137 7:1287065 cg12560987 233619 0.137 STL 6:125283953 cg10621825 201643 0.137 FAM181B 11:82444798 cg09617579 184158 0.137 DACH2 X:85402643 cg16259355 299014 0.137 13:21872234 cg11317459 213174 0.137 IRX4 5:1882885 cg14507560 269807 0.137 FGD3 9:95737070 cg14263098 264963 0.137 7:157477846 cg04207084 84494 0.137 AATF; LHX1 17:35300010 cg19760241 356113 0.137 HES6; LOC151174; 2:239149859 cg24127874 424152 LOC643387; PER2 0.137 HOXD4; MIR10B 2:177014962 cg00014998 368 0.137 C5orf63 5:126409308 cg21113900 376968 0.137 SLC16A11; SLC16A13 17:6946059 cg19639560 354003 0.137 ZBTB44 11:130185651 cg14482569 269324 0.137 ARHGEF4 2:131674140 cg07815799 152125 0.137 DAXX; TAPBP; 6:33280424 cg26083458 455084 ZBTB22 0.137 DPP10; LOC389023 2:115919829 cg01718116 35249 0.137 OR2H1 6:29427519 cg05111645 101800 0.137 HAS1; LINC00085 19:52206667 cg17519645 320492 0.137 TGFBI 5:135364580 cg09873933 188549 0.138 NAALAD2 11:89867637 cg16886581 310118 0.138 14:95331190 cg03459776 69950 0.138 FOXF2 6:1390622 cg12221475 228386 0.138 THRB 3:24537050 cg27526665 479998 0.138 7:156400779 cg18584424 337608 0.138 MIR3663 10:118922493 cg24234899 425848 0.138 PITX1 5:134364387 cg00396667 8373 0.138 DRD5 4:9783198 cg03045635 62021 0.138 SIK3 11:116857794 cg09458566 181396 0.138 13:109147921 cg03994318 80330 0.138 IGF2BP1 17:47075880 cg02745847 55935 0.138 SKINTL 1:48559803 cg08871545 171173 0.138 LMX1A 1:165204796 cg09118258 175320 0.138 GATA6 18:19756877 cg12615165 234584 0.138 CYB561D2; NPRL2; 3:50383079 cg20881888 373460 RASSF1; TMEM115; ZMYND10 0.138 NXNL1; TMEM221 19:17559217 cg18380550 334165 0.138 C12orf53 12:6818384 cg23877043 419727 0.138 TAL1 1:47691158 cg10380348 197448 0.139 ALPK3 15:85360664 cg20318166 364967 0.139 VSTM2A 7:54614620 cg06139908 120728 0.139 15:26108391 cg03419058 69144 0.139 OPCML 11:132813563 cg18710784 339517 0.139 HOXA5; HOXA6; 7:27187560 cg14044640 260386 HOXA7; LOC100133311 0.139 6:27525678 cg20494374 367603 0.139 KDM1A; MIR3115 1:23361764 cg25002551 438359 0.139 RLF 1:40626599 cg18646240 338570 0.139 NRSN2 20:328035 cg21192095 378373 0.139 MSX1 4:4864430 cg24840099 435675 0.139 FLJ16779; NKAIN4 20:61886079 cg08111446 157414 0.139 DUSP4 8:29210154 cg13635007 251899 0.139 MAGI2-AS3 7:79083509 cg24021956 422308 0.139 H2AFY 5:134735637 cg15613420 288307 0.139 PLD3 19:40871823 cg08360726 162147 0.140 KIRREL3; ST3GAL4 11:126286828 cg12804791 237513 0.140 ASIP 20:32856846 cg16440058 302309 0.140 NKAIN3 8:63161609 cg15858239 292441 0.140 SMAD3 15:67396487 cg19193595 346888 0.140 ALPK3 15:85360655 cg25895948 452116 0.140 C8orf83 8:93977794 cg16560711 304445 0.140 MSX1 4:4864532 cg09748975 186296 0.140 ACTN3; CTSF 11:66326798 cg05475524 108647 0.141 DPP6 7:153584873 cg14564076 271091 0.141 CTNNA2 2:79740185 cg19707040 355066 0.141 SOX1 13:112721325 cg24604013 431705 0.141 DOCK1; FAM196A 10:128994297 cg06525651 127283 0.141 SLC6A18; SLC6A19 5:1222847 cg04248937 85368 0.141 C14orf23; FOXG1 14:29236898 cg07489048 146092 0.141 NANS 9:100819928 cg13527921 249630 0.141 11:44545144 cg13759632 254444 0.141 LRP12 8:105601036 cg24098951 423650 0.141 COL23A1 5:178004091 cg08475953 164148 0.141 ASGR1 17:7077709 cg03975755 79935 0.141 11:133837265 cg23152235 408116 0.141 SIM2 21:38070671 cg26938272 470089 0.141 SCN2B; SCN4B 11:118023765 cg18718634 339649 0.141 FZD5 2:208631684 cg15714846 290094 0.141 DOCK1 10:128593946 cg23665778 416569 0.141 INPP5A; NKX6-2 10:134600701 cg17996619 327663 0.141 ONECUT2 18:55095249 cg15222899 282298 0.141 ZDHHC4 7:6616423 cg19149522 346313 0.141 OR10AD1 12:48592721 cg23748340 417996 0.142 NLRP2 19:55477759 cg19689876 354758 0.142 NXPH2 2:139537845 cg00804628 16987 0.142 FAIM3; IL24 1:207082828 cg06528575 127352 0.142 ZC3H3 8:144599125 cg13071618 241523 0.142 FAM84A 2:14775046 cg05602862 110952 0.142 FAM84A 2:14773973 cg16846645 309527 0.142 HMX3 10:124897048 cg15396686 284826 0.142 RNF207; RPL22 1:6269260 cg15731815 290408 0.142 LOC100188947 10:93058549 cg04285822 86104 0.142 HOOK1 1:60280812 cg15900248 293091 0.142 DRD5 4:9783196 cg23847712 419333 0.142 CNTN4 3:2140256 cg04222358 84827 0.142 3:159818742 cg07617768 148563 0.142 GLRB 4:157997367 cg16269431 299215 0.143 2:68917482 cg18670846 338907 0.143 8:41624841 cg07162571 140077 0.143 MTUS2 13:30055092 cg05122437 101967 0.143 FAM110B 8:59058254 cg13247663 244256 0.143 2:92027943 cg27311294 476418 0.143 TNR 1:175568559 cg24932457 437299 0.143 TNIP3 4:122078348 cg26832294 468154 0.143 C5orf63 5:126409007 cg10200291 194305 0.143 BCOR X:40012100 cg06548617 127783 0.143 11:32008961 cg20019985 360529 0.143 OCRL X:128674224 cg05032353 100321 0.143 CHST8 19:34113010 cg16190732 297843 0.143 UBD 6:29520774 cg08065408 156530 0.143 PCDHGA1; PCDHGA10; 5:140787430 cg07613945 148493 PCDHGA2; PCDHGA3; PCDHGA4; PCDHGA5; PCDHGA6; PCDHGA7; PCDHGA8; PCDHGA9; PCDHGB1; PCDHGB2; PCDHGB3; PCDHGB4; PCDHGB5; PCDHGB6; PCDHGB7 0.143 SYT15 10:46970625 cg09373037 179902 0.143 FOXI2 10:129535669 cg07918545 153959 0.144 LOC649133; POU2F3 11:120110882 cg26357587 459979 0.144 CSMD1 8:4849827 cg23495279 413823 0.144 OSTalpha; ZDHHC19 3:195934355 cg26292150 458748 0.144 PITX1 5:134363877 cg04223420 84848 0.144 PDZRN4 12:41582362 cg16896079 310254 0.144 SH2D4B 10:82295864 cg15642854 288829 0.144 UNC80 2:210636560 cg04100532 82347 0.144 CYB561D2; NPRL2; 3:50383118 cg11270070 212403 RASSF1; TMEM115; ZMYND10 0.144 DPP6 7:153749756 cg15549927 287181 0.144 HCN1 5:45695643 cg18273840 332528 0.144 LHX8 1:75602167 cg08272731 160551 0.145 UBD 6:29521420 cg22305167 394855 0.145 ADAMTS20 12:43945892 cg19619405 353636 0.145 HAGH 16:1863053 cg00935504 19660 0.145 ISM1 20:13200931 cg04432319 88934 0.145 ANKS1B 12:99288805 cg03609960 73052 0.145 LHX3 9:139085579 cg04455058 89330 0.145 6:10382103 cg20906291 373785 0.145 FAM110B 8:59058273 cg12615766 234593 0.145 CYP1A1 15:75018852 cg20004910 360290 0.145 CACNB2 10:18429703 cg02456226 50000 0.145 SNTG2 2:1134065 cg16519574 303633 0.145 DPYS 8:105478855 cg16783744 308581 0.145 19:57618136 cg18384778 334232 0.145 2:200524189 cg20711639 371065 0.145 HLA- 6:33053608 cg01991743 40852 DPA1; HLA- DPB1 0.146 GNG12; LOC100289178 1:68299409 cg13184736 243235 0.146 NAALAD2 11:89867679 cg18540157 336897 0.146 1:241520286 cg14156405 262603 0.146 18:4455337 cg25627226 448224 0.146 PLSCR2 3:146187126 cg24092307 423558 0.146 MAD2L1BP; RSPH9 6:43612908 cg17536595 320768 0.146 GALNT10 5:153569246 cg13372456 246337 0.146 KCNA4 11:30038675 cg08490115 164399 0.146 7:158380886 cg27392792 477814 0.146 KY 3:134369661 cg24675998 432827 0.146 IRF6 1:209979624 cg09509183 182272 0.147 7:156400881 cg27483342 479249 0.147 ZSCAN1 19:58545333 cg27391267 477779 0.147 NAALAD2 11:89867704 cg21817737 387693 0.147 NID1 1:236228741 cg07157830 139963 0.147 TCHH 1:152079713 cg16689481 306872 0.147 ZBTB44 11:130185670 cg05227350 103986 0.147 AGAP1 2:236412034 cg11045331 208636 0.147 KDM2B 12:122019006 cg07793808 151670 0.147 KIF12 9:116860650 cg14326196 266248 0.148 FAM150A 8:53477881 cg09442654 181101 0.148 ADAP1 7:968552 cg05904016 116371 0.148 DOCK1; FAM196A 10:128994644 cg03129384 63592 0.148 MAML2 11:95969587 cg05270552 104870 0.148 SP8 7:20824932 cg23093589 407294 0.148 12:119212248 cg22125805 392264 0.148 ZSCAN18 19:58609618 cg22721334 401040 0.148 FOSB 19:45976195 cg12542255 233333 0.148 ZSCAN18 19:58609602 cg25784220 450602 0.148 GALR1 18:74962672 cg06360427 124375 0.148 5:168728081 cg07136998 139473 0.148 ANKRD18A; FAM201A 9:38622559 cg21189438 378326 0.148 CSGALNACT2; 10:43633030 cg07178550 140402 RET 0.148 13:53775410 cg13974192 258762 0.149 DIAPH1; PCDHGA12; 5:140892822 cg08860070 170948 PCDHGC3; PCDHGC4; PCDHGC5 0.149 DNAAF2; LRR1; 14:50084155 cg22857670 403218 MGAT2; RPL36AL 0.149 MACROD2; SEL1L2 20:13976096 cg01552272 32076 0.149 MYH13 17:10220829 cg13984289 259022 0.149 22:20284604 cg00192046 4240 0.149 CCDC148; PKP4 2:159312727 cg14426788 268232 0.149 1:23544995 cg19743168 355780 0.150 GLRB 4:157997360 cg22065614 391410 0.150 16:51671357 cg07302051 142686 0.150 ZFP42 4:188916943 cg14189571 263343 0.150 UBD 6:29520752 cg11935738 223492 0.150 CPSF3; IAH1 2:9614225 cg08047252 156223 0.150 GP9 3:128787213 cg20264543 364127 0.150 CCR6 6:167559851 cg02524205 51410 0.150 EFCAB1 8:49647809 cg11469098 215629 0.150 IRX4 5:1876397 cg14451382 268670 0.150 ARHGAP23 17:36666642 cg15825321 291821 0.150 CLEC14A 14:38724648 cg16404157 301618 0.150 CACNA2D3 3:54155663 cg18143243 330278 0.151 BTG4; C11orf88; 11:111383624 cg23211240 409137 MIR34B; MIR34C 0.151 GTF3A; MTIF3 13:28016624 cg26772116 467001 0.151 16:49499006 cg01517680 31431 0.151 CTTN 11:70262058 cg16629523 305772 0.151 CCDC106; U2AF2; 19:56159485 cg08496742 164543 ZNF580; ZNF581 0.152 DQX1; PCGF1; 2:74743009 cg07203423 140895 TLX2 0.152 KCNIP1 5:169960825 cg10931884 206704 0.152 MAL2 8:120220856 cg02225716 45426 0.152 GDF6 8:97173034 cg21859781 388371 0.152 HOXC4; HOXC5; 12:54424203 cg13826247 255805 HOXC6; MIR615 0.152 NCAM1 11:112831501 cg21727486 386364 0.152 ZNF503; ZNF503- 10:77156697 cg25023298 438769 AS2 0.152 MDGA1 6:37616803 cg24442454 429044 0.152 SHROOM2 X:9754927 cg05782106 114103 0.152 4:1515011 cg08480901 164253 0.153 NXPH2 2:139537826 cg14923640 277390 0.153 BDNF 11:27740813 cg13974632 258776 0.153 3:74663689 cg24346629 427487 0.153 4:1400189 cg24496475 429912 0.153 14:97058777 cg11871960 222513 0.154 ATP2C2 16:84402158 cg07507755 146441 0.154 7:32358540 cg27511599 479742 0.154 INTU 4:128544375 cg26114043 455622 0.154 PNLIPRP2 10:118387207 cg18699744 339327 0.154 WIPI2 7:5271480 cg26660312 465112 0.154 GALNTL6 4:172734431 cg22153181 392677 0.154 MSI2 17:55362836 cg07249730 141786 0.154 LIN9; MIXL1 1:226411057 cg18564989 337293 0.154 GPR125 4:22520573 cg13702087 253322 0.155 MMP16 8:89340139 cg12818557 237751 0.155 11-Mar 5:16179660 cg09017434 173718 0.155 5:143978357 cg11527001 216436 0.155 ADAMTS16 5:5140001 cg22954449 404825 0.155 PITX1 5:134365728 cg18606375 337970 0.155 10:109674526 cg00157668 3542 0.155 TSHZ1; ZADH2 18:72916393 cg11568697 217092 0.155 2:240135921 cg18121901 329904 0.155 LYPD1; NCKAP5 2:133427612 cg25571189 447240 0.155 NAALAD2 11:89867809 cg12403137 230998 0.155 HOXC8; HOXC9 12:54396990 cg22679316 400266 0.155 ANKRD36B 2:98206733 cg23224356 409392 0.156 NKAIN3 8:63161589 cg08855288 170823 0.156 RPS7P5 1:240161445 cg21854408 388273 0.156 12:116354837 cg20169823 362815 0.156 GABRA5 15:27112902 cg03462380 70010 0.156 UNCX 7:1267228 cg11715858 219570 0.156 TNIP3 4:122078167 cg10061361 191660 0.156 CDH11 16:65157428 cg07537692 146986 0.156 DNAJB6 7:157192974 cg25039694 439065 0.156 DOCK1; FAM196A 10:128994432 cg03242819 65770 0.156 ADAMTSL1 9:18514052 cg14470762 269062 0.157 CPNE9; MTMR14 3:9745610 cg02741521 55842 0.157 KIF25 6:168436099 cg18319852 333241 0.157 PIN4 X:71401206 cg26578373 463841 0.157 ANKRD36BP2 2:89065379 cg02646394 53977 0.157 PXDN 2:1748132 cg25181651 441181 0.158 GPR78 4:8582227 cg18901644 342716 0.158 ADAMTS16 5:5139797 cg16670809 306536 0.158 18:6414974 cg18556788 337142 0.158 GRM7 3:6903019 cg27199820 474552 0.158 CBWD2; FOXD4L1 2:114261369 cg23850283 419371 0.158 DPP10; LOC389023 2:115919006 cg03753331 75826 0.158 MIR4634 5:174178693 cg12398645 230921 0.159 SEMA3C 7:80548456 cg03823904 77109 0.159 DHRS4L2 14:24476559 cg10926857 206629 0.159 WBSCR17 7:70597058 cg02300154 46944 0.159 11:2367787 cg20805368 372479 0.159 NTM 11:131781257 cg19717586 355276 0.159 FLJ31485; FZD10 12:130647004 cg21885046 388782 0.160 CBLN1 16:49316197 cg03389653 68591 0.160 GBX2 2:237076815 cg19761848 356155 0.160 BCOR X:40035961 cg00016934 407 0.160 HS3ST2 16:22825046 cg09191731 176695 0.160 ZNF148 3:125076372 cg02970696 60506 0.160 PROZ 13:113819073 cg00898013 18847 0.160 2:130971164 cg08566455 165743 0.160 7:32467657 cg18961681 343589 0.160 7:152621979 cg08202754 159199 0.161 FEZF1; LOC154860 7:121946036 cg10485664 199138 0.161 NKAIN3 8:63161579 cg01906015 39032 0.161 PROCA1; RAB34; 17:27044629 cg21816330 387671 RPL23A; SNORD42A; SNORD42B; SNORD4A; SNORD4B; TLCD1 0.161 DOCK1 10:128593922 cg06128198 120545 0.161 HTR4 5:148033882 cg11438011 215195 0.161 PITX1 5:134363973 cg07274716 142211 0.161 UHRF1BP1 6:34760872 cg07306190 142760 0.161 IRX4 5:1887300 cg07565505 147521 0.161 SOX17 8:55370429 cg11214140 211422 0.161 GRHL2 8:102505986 cg03650674 73811 0.162 ABCB11; G6PC2 2:169769616 cg05703053 112745 0.162 18:6729810 cg02824202 57399 0.162 GALR1 18:74962000 cg17911318 326333 0.162 KCNA4 11:30038672 cg15044957 279439 0.162 CNTNAP2 7:145813421 cg21126583 377176 0.162 NID1 1:236228744 cg04837025 96465 0.162 THRB 3:24536474 cg20985755 375077 0.162 COBL 7:51384371 cg12988534 240269 0.162 GDF7 2:20870362 cg07755735 151051 0.162 ARHGAP33; C19orf55 19:36265700 cg18805164 341126 0.163 8:143070187 cg06573787 128217 0.163 ERG 21:40033163 cg12884169 238711 0.163 PON2; PON3 7:95025736 cg07121856 139138 0.163 HOXD10; HOXD11; 2:176972563 cg11546137 216732 HOXD12 0.164 NSUN4 1:46814106 cg15580309 287719 0.164 CYB561D2; NPRL2; 3.50383167 cg09682796 185261 RASSF1; TMEM115; ZMYND10 0.164 CHL1 3:239665 cg10603275 201352 0.164 MYOG; PPFIA4 1:203045044 cg00805880 17008 0.165 GNAI1 7:79764178 cg25744767 449994 0.165 LOC649133; POU2F3 11:120110887 cg17176573 314750 0.165 11-Mar 5:16179633 cg23479922 413567 0.165 PSMB9; TAP1 6:32829303 cg05062939 100976 0.165 TMEM229A 7:123673331 cg17025835 312249 0.165 CEND1; PDDC1; 11:783889 cg01741372 35661 SLC25A22 0.166 DOCK1 10:128593943 cg22665692 400049 0.166 ATP6V1A 3:113502832 cg19924544 358964 0.166 C6orf147; KHDC1 6:74024628 cg02447304 49827 0.166 22:43168851 cg24694833 433260 0.167 FAT1 4:187645118 cg01244944 26097 0.167 LILRB3 19:54728037 cg23679434 416846 0.167 SYT14 1:210111561 cg19922137 358920 0.167 ZNF844 19:12175935 cg26827373 468055 0.167 EVX2; HOXD12; 2:176957842 cg04415176 88629 HOXD13 0.167 10:131762462 cg07045241 137620 0.167 KLF8 X:56259243 cg06457357 126059 0.168 C5orf63 5:126408756 cg14340928 266559 0.168 MAGI2-AS3 7:79083408 cg22280038 394533 0.168 4:21950567 cg00688962 14541 0.169 SHISA6 17:11144043 cg13330559 245613 0.169 ARSG; SLC16A6 17:66287032 cg11879514 222640 0.169 RNF180 5:63461654 cg17370163 317926 0.169 DACH1 13:72439698 cg05510902 109333 0.169 7:55516724 cg03357999 68033 0.169 EPB41L3 18:5543801 cg00027083 665 0.170 11:67499431 cg02666610 54357 0.170 CCT8L2; TPTEP1 22:17082772 cg01660911 34237 0.171 UBTD1 10:99278449 cg10989317 207724 0.171 18:6414976 cg14352983 266773 0.171 WBSCR17 7:70597065 cg03044249 61987 0.171 MYO16 13:109352806 cg24702069 433391 0.171 ANKRD36 2:97778927 cg12623145 234729 0.171 7:152622022 cg15818671 291676 0.171 SP8 7:20824706 cg01003961 21140 0.172 CTTNBP2 7:117513101 cg05951860 117342 0.172 NAT2 8:18244861 cg12174804 227617 0.172 WBSCR17 7:70597921 cg07143083 139618 0.172 THRB 3:24536478 cg13790603 255057 0.172 16:85368973 cg02418439 49379 0.173 UBD 6:29521356 cg21632158 385088 0.173 ADAMTSL3 15:84322584 cg04138185 83155 0.173 RAB32 6:146864885 cg26252281 458030 0.174 CLEC14A 14:38724675 cg05057720 100847 0.174 DOCK1; FAM196A 10:128994603 cg03070297 62543 0.174 MDGA1 6:37618009 cg26720545 466246 0.174 BAIAP2L1 7:98029266 cg08684580 167809 0.174 LRRC4C 11:40314978 cg19849428 357643 0.174 8:7079106 cg08498719 164579 0.174 FAM43B 1:20879547 cg12768681 236962 0.174 SEMA5B 3:122694286 cg07733481 150639 0.175 SGPP2 2:223289306 cg07357987 143728 0.175 8:76320150 cg26220018 457454 0.175 CDH2 18:25757710 cg14312538 265980 0.175 CR1L 1:207842917 cg17822947 324851 0.175 NOVA1 14:27067372 cg20478129 367360 0.176 CACNA1B 9:140917431 cg13610307 251390 0.176 TRAF3 14:103367591 cg10920224 206529 0.176 IRX1 5:3596207 cg10530883 200071 0.176 BTBD3 20:11871384 cg23944804 420919 0.177 10:111216962 cg16664405 306435 0.177 10:125751413 cg20250269 363883 0.178 IRS2 13:110438578 cg02320481 47382 0.178 EVX2; HOXD13 2:176948732 cg15133351 280970 0.178 PKDCC 2:42275740 cg12630082 234855 0.179 IL5RA 3:3152916 cg21594961 384489 0.179 C5orf63 5:126408806 cg17848407 325324 0.179 GDF7 2:20870812 cg14780466 274979 0.179 HOXA10; HOXA10- 7:27206073 cg15506609 286583 HOXA9; HOXA7; HOXA9; MIR196B 0.179 TMCC3 12:94995915 cg09162806 176158 0.179 LOC91149; RAPGEF4 2:173600676 cg00997611 21009 0.179 PHACTR1 6:12749978 cg13246235 244239 0.180 GCK; MYL7 7:44184403 cg03812172 76924 0.181 9:98981500 cg21167269 377918 0.181 GDF7 2:20870087 cg09074113 174642 0.181 KCNE1 21:35832028 cg07321776 143076 0.181 KCNK2 1:215256262 cg18794839 340940 0.181 GPR123 10:134910540 cg13750264 254277 0.182 FTSJ2; NUDT1; 7:2289097 cg12017558 224816 SNX8 0.182 KLF16 19:1852127 cg07355926 143681 0.182 2:154143768 cg18771570 340550 0.183 6:77563066 cg21291856 380079 0.184 17:54858770 cg07973125 154969 0.184 FGF12 3:192127457 cg08002883 155463 0.185 ILDR1 3:121714668 cg20356878 365522 0.185 SLC17A3 6:25882590 cg03517284 71065 0.186 FHOD3 18:34325827 cg07495405 146206 0.186 C1orf106 1:200860534 cg00909514 19113 0.186 HOXA5; HOXA6; 7:27187502 cg03529432 71326 HOXA7; LOC100133311 0.186 SH2D4B 10:82295502 cg08506606 164700 0.186 KNDC1; UTF1; 10:135044114 cg09053680 174307 VENTX 0.186 GSC2 22:19137874 cg23774356 418306 0.186 CLCA1 1:86968087 cg19807991 356943 0.187 SCTR 2:120281999 cg07176264 140350 0.187 PITX1 5:134363562 cg02037307 41774 0.187 FTSJ2; NUDT1; 7:2288716 cg13550401 250077 SNX8 0.188 8:7543899 cg12174280 227610 0.189 CLCA1 1:86968543 cg04896168 97717 0.190 NAALAD2 11:89867911 cg14304817 265815 0.190 LHX6 9:124989294 cg21469772 382370 0.190 KLF16 19:1852165 cg05006231 99848 0.191 CLCA1 1:86968255 cg26829098 468093 0.191 HLA-A 6:29910755 cg11808100 221232 0.192 19:22444593 cg03692651 74585 0.192 SERTM1 13:37248244 cg09907509 189121 0.193 CNTN4 3:2140699 cg06598836 128644 0.193 15:29862517 cg04283162 86040 0.193 4:56023751 cg10360906 197083 0.193 KIAA1217; PRINS 10:24535410 cg04122385 82818 0.194 C5orf63 5:126409211 cg10812634 204796 0.194 LOC91149; RAPGEF4 2:173600362 cg14379854 267268 0.195 ZNF471 19:57019069 cg00674365 14254 0.195 AFG3L1P; DBNDD1 16:90070038 cg16380389 301186 0.195 SH2D4B 10:82296072 cg09981929 190306 0.196 C21orf67; ITGB2; 21:46349496 cg02464073 50169 LOC100505746 0.196 NPTX2 7:98246633 cg18952796 343455 0.197 LHX6 9:124990276 cg00142257 3190 0.197 GDF7 2:20871401 cg04082016 81976 0.197 CR1L 1:207842833 cg03408135 68966 0.198 DKFZP686I15217; 6:2991147 cg06195525 121679 NQO2 0.199 PCDH7 4:30723855 cg26133769 455996 0.199 IFITM1; IFITM3 11:320956 cg14885742 276796 0.199 GNAS; GNAS- 20:57414274 cg23732978 417791 AS1 0.201 NAALAD2 11:89867819 cg05500015 109117 0.202 CPNE4 3:131246020 cg01966816 40359 0.204 EFHA2 8:16885000 cg12097222 226305 0.204 CRMP1 4:5894691 cg03544320 71665 0.205 UNC5D 8:35092876 cg06010588 118507 0.206 WTIP 19:34972145 cg10771931 204037 0.207 DNAH2; EFNB3; 17:7613764 cg22098780 391853 WRAP53 0.207 CR1L 1:207843084 cg21106486 376853 0.207 CR1; CR2 1:207669922 cg10021878 191017 0.207 13:21872349 cg14456004 268764 0.207 LOC645249 7:156814480 cg09858188 188213 0.208 13:50701619 cg01803928 36963 0.208 GALR1 18:74962133 cg03502002 70747 0.210 1:239550283 cg13985485 259057 0.210 9:96623674 cg13679303 252812 0.210 DRD5 4:9783192 cg26296488 458826 0.210 NETO1 18:70535005 cg18651870 338661 0.211 MDGA1 6:37617124 cg00807871 17056 0.212 FAM75C1 9:90531866 cg21265404 379726 0.213 TNS3 7:47621692 cg06352730 124250 0.214 2:16484904 cg23905015 420220 0.214 7:32358064 cg13207630 243593 0.216 PROZ 13:113819100 cg18105134 329535 0.216 TSHZ1; ZADH2 18:72917101 cg18449964 335368 0.217 C5orf63 5:126409310 cg15405432 284960 0.218 ZNF468 19:53361448 cg15721243 290213 0.219 FAT1 4:187644739 cg16248329 298797 0.220 CTTNBP2 7:117513835 cg16913250 310581 0.220 HES6; LOC151174; 2:239139911 cg06102419 120125 LOC643387 0.221 MAL2 8:120220882 cg06822816 133139 0.222 C5orf63 5:126409227 cg02304092 47036 0.224 LHX6 9:124988720 cg04282082 86021 0.226 HCG4; LOC554223 6:29759078 cg11036359 208507 0.229 C5orf63 5:126409061 cg18710053 339507 0.229 GPR78 4:8582249 cg01829241 37555 0.229 LHX6 9:124989337 cg13571460 250561 0.230 C5orf63 5:126409198 cg22905511 404065 0.231 2:154143677 cg07563363 147470 0.233 FCRLA 1:161675579 cg04888234 97564 0.233 FAM160B1 10:116634877 cg14964115 278020 0.235 PM20D1 1:205819251 cg14893161 276892 0.235 GDF7 2:20871279 cg07021052 137180 0.237 ANKRD27; RGS9BP 19:33165484 cg27413643 478153 0.238 MDGA1 6:37617864 cg20053110 361003 0.240 18:6414978 cg17688525 322822 0.244 ATP8B5P; RUSC2 9:35490515 cg15271616 283055 0.244 GDF7 2:20871002 cg10687131 202734 0.248 2:181987552 cg20685672 370518 0.252 ARHGAP33; C19orf55 19:36264029 cg16569309 304609 0.252 LHX6 9:124990165 cg03363289 68128 0.253 GDF7 2:20870211 cg05481257 108752 0.253 SH2D4B 10:82295723 cg24440658 429013 0.254 GDF7 2:20869434 cg27141850 473604 0.254 TSNARE1 8:143376371 cg24849373 435844 0.254 AGAP1 2:236579469 cg03451670 69806 0.255 1:41350183 cg08870646 171150 0.255 LHX6 9:124989915 cg13862711 256498 0.256 IGF1R 15:99193247 cg03437748 69502 0.256 SDK1 7:4118583 cg22535849 398182 0.257 PM20D1 1:205819492 cg24503407 430027 0.258 CLCA1 1:86968184 cg10760651 203838 0.259 WDR17 4:176987009 cg11923920 223292 0.261 ACAN 15:89354338 cg02401352 49110 0.266 TSHZ1; ZADH2 18:72917163 cg03972071 79876 0.269 MDGA1 6:37617956 cg24796644 434985 0.272 C5orf63 5:126409153 cg27097438 472827 0.275 C11orf67; RSF1 11:77532707 cg22741595 401343 0.275 6:167195910 cg06330797 123893 0.276 COL9A1 6:71022072 cg23974730 421453 0.276 INPP5A 10:134411480 cg12501287 232697 0.277 PM20D1 1:205818956 cg17178900 314798 0.277 FAM181A; FAM181A- 14:94385395 cg20022541 360557 AS1 0.279 3:120151283 cg06378561 124751 0.280 LOC255411 12:49113738 cg00007810 182 0.280 CHAF1B 21:37761363 cg22871721 403496 0.281 ASB1 2:239330383 cg13295614 245013 0.282 TNFSF8 9:117694183 cg14361804 266932 0.284 DISC1 1:231820076 cg07134368 139412 0.285 DIP2C 10:593275 cg06051619 119189 0.286 ULK4P1; ULK4P2 15:30861172 cg23804921 418678 0.287 TPO 2:1426786 cg01957222 40112 0.288 PM20D1 1:205819463 cg07167872 140186 0.290 PM20D1 1:205819179 cg14159672 262672 0.290 LOC200772 2:241896910 cg06193597 121647 0.291 PM20D1 1:205819406 cg11965913 224049 0.292 PPP2R2B 5:146253830 cg10926851 206628 0.294 LOC100133461 4:3683268 cg03965172 79742 0.297 AVL9; LSM5 7:32526065 cg26856631 468599 0.300 PM20D1 1:205819088 cg26354017 459920 0.300 MIR182; MIR183; 7:129412730 cg16069065 295914 MIR96 0.301 SCN1A 2:166930521 cg00881894 18574 0.305 RPSAP58; ZNF681 19:23941859 cg25958450 453100 0.305 CCDC130; MRI1 19:13875111 cg25755428 450171 0.317 PML 15:74345103 cg11399582 214535 0.318 C1orf109; CDCA8 1:38156652 cg06917450 135153 0.324 CELF4 18:34917603 cg20094343 361624 0.325 CLEC4F 2:71033156 cg02479782 50493 0.343 EHMT2; NEU1; 6:31838544 cg20370184 365714 SLC44A4 0.344 NCOR2 12:124827315 cg23878260 419752 0.349 PCCA 13:100989375 cg20536971 368191 0.351 ANKRD26P3; 13:19918525 cg08801017 169810 LINC00421 0.355 PPYR1 10:47083392 cg11861387 222311 0.358 5:5887642 cg26690407 465769 0.363 13:79694063 cg24941469 437468 0.366 ALLC 2:3753297 cg05971102 117729 0.378 MIR3663 10:118931160 cg17723206 323281 0.388 SERPINB9 6:2888212 cg19577958 352915 0.399 NCOR2 12:124831017 cg07474670 145798 0.404 14:22370643 cg12819537 237764 0.408 SLC37A1 21:43989949 cg08407901 162897 0.413 MRPL1 4:78852682 cg15897435 293045 0.417 C7orf26; ZNF853 7:6653510 cg08693140 167967 0.431 14:22361282 cg16702660 307151 0.432 ITIH4; MUSTN1; 3:52869263 cg24629711 432072 TMEM110; TMEM110- MUSTN1 0.442 MAGI2-AS3 7:79083056 cg14464244 268938 0.586 PPP1R16B 20:37438823 cg18674961 338963 *UCSC hg19 Cytosine Coordinate of CpG (+strand)

The term “comprising” as used herein is synonymous with “including,” “containing,” or “characterized by,” and is inclusive or open-ended and does not exclude additional, unrecited elements or method steps.

All numbers expressing quantities of ingredients, reaction conditions, and so forth used in the specification are to be understood as being modified in all instances by the term “about.” Accordingly, unless indicated to the contrary, the numerical parameters set forth herein are approximations that may vary depending upon the desired properties sought to be obtained. At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the scope of any claims in any application claiming priority to the present application, each numerical parameter should be construed in light of the number of significant digits and ordinary rounding approaches.

The above description discloses several methods and materials of the present invention. This invention is susceptible to modifications in the methods and materials, as well as alterations in the fabrication methods and equipment. Such modifications will become apparent to those skilled in the art from a consideration of this disclosure or practice of the invention disclosed herein. Consequently, it is not intended that this invention be limited to the specific embodiments disclosed herein, but that it cover all modifications and alternatives coming within the true scope and spirit of the invention.

The following references are incorporated herein by reference in their entireties.

REFERENCES

-   1 Firestein G S. Evolving concepts of rheumatoid arthritis. Nature,     423:356-361, 2003 -   2 Lee differentially methylated, Kiener H P, Agarwal S K, Noss E H,     Watts G F, Chisaka O, Takeichi M, Brenner M B. 2007. Cadherin-11 in     synovial lining formation and pathology in arthritis. Science.     315:1006 -   3 Kiener H P, Niederreiter B, Lee differentially methylated,     Jimenez-Boj E, Smolen J S, Brenner M B. Cadherin 11 promotes     invasive behavior of fibroblast-like synoviocytes. Arthritis Rheum.     2009 May; 60(5):1305-10 -   4 Firestein, G S. Invasive fibroblast-like synoviocytes in     rheumatoid arthritis: Passive responders or transformed aggressors?     Arthritis Rheum 39:1781-1790, 1996 -   5 Müller-Ladner U, Kriegsmann J, Franklin B N, Matsumoto S, Geiler     T, Gay R E, Gay S. Synovial fibroblasts of patients with rheumatoid     arthritis attach to and invade normal human cartilage when engrafted     into SCID mice. Am J Pathol. 1996 November; 149(5):1607-15 -   6 Lafyatis R, Remmers E F, Roberts A B, Yocum D E, Sporn M B, Wilder     R L. 1989. Anchorage-independent growth of synoviocytes from     arthritic and normal joints. Stimulation by exogenous     platelet-derived growth factor and inhibition by transforming growth     factor-beta and retinoids. J Clin Invest. 83:1267 -   7 Baier A, Meineckel I, Gay S, Pap T. Apoptosis in rheumatoid     arthritis. Curr Opin Rheumatol. 2003 May; 15(3):274-9 -   8 Lefèvre S, Knedla A, Tennie C, Kampmann A, Wunrau C, Dinser R,     Korb A, Schnäker E M, Tamer I H, Robbins P D, Evans C H, Stürz H,     Steinmeyer J, Gay S, Schölmerich J, Pap T, Müller-Ladner U,     Neumann E. Synovial fibroblasts spread rheumatoid arthritis to     unaffected joints. Nat Med. 2009 December; 15(12):1414-20 -   9 Pap T, Franz J K, Hummel K M, Jeisy E, Gay R, Gay S. Activation of     synovial fibroblasts in rheumatoid arthritis: lack of Expression of     the tumour suppressor PTEN at sites of invasive growth and     destruction. Arthritis Res. 2000; 2(1):59-64 -   10 Franz J K, Pap T, Hummel K M, Nawrath M, Aicher W K, Shigeyama Y,     Müller-Ladner U, Gay R E, Gay S. Expression of sentrin, a novel     antiapoptotic molecule, at sites of synovial invasion in rheumatoid     arthritis. Arthritis Rheum. 2000 March; 43(3):599-607 -   11 You X, Boyle D L, Hammaker D, Firestein G S. PUMA-mediated     apoptosis in fibroblast-like synoviocytes does not require p53.     Arthritis Res Ther. 2006; 8(6):R157 -   12 Firestein G S, F Echeverri, M Yeo, N J Zvaifler, and D R Green.     Somatic mutations in the p53 tumor suppressor gene in rheumatoid     arthritis synovium. Proc Natl Acad Sci USA, 94: 10895-10900, 1997 -   13 Igarashi H, Hashimoto J, Tomita T, Yoshikawa H, Ishihara K. TP53     mutations coincide with the ectopic expression of activation-induced     cytidine deaminase in the fibroblast-like synoviocytes derived from     a fraction of patients with rheumatoid arthritis. Clin Exp Immunol.     2010 Jul. 1; 161(1):71-80 -   14 Inazuka M, Tahira T, Horiuchi T, Harashima S, Sawabe T, Kondo M,     Miyahara H, Hayashi K. Analysis of p53 tumour suppressor gene     somatic mutations in rheumatoid arthritis synovium. Rheumatology     (Oxford). 2000 March; 39(3):262-6 -   15 Rème T, Travaglio A, Gueydon E, Adla L, Jorgensen C, Sany J.     Mutations of the p53 tumour suppressor gene in erosive rheumatoid     synovial tissue. Clin Exp Immunol. 1998 February; 111(2):353-8 -   16 Bang H, Egerer K, Gauliard A, Lüthke K, Rudolph P E, Fredenhagen     G, Berg W, Feist E, Burmester G R. Mutation and citrullination     modifies vimentin to a novel autoantigen for rheumatoid arthritis.     Arthritis Rheum. 2007 August; 56(8):2503-11 -   17 Da Sylva T R, Connor A, Mburu Y, Keystone E, Wu G E. Somatic     mutations in the mitochondria of rheumatoid arthritis synoviocytes.     Arthritis Res Ther. 2005; 7(4):R844-51 -   19 Lee S-H, D K Chang, A Goel, C R Boland, W Bugbee, D L Boyle, and     G S Firestein. Microsatellite instability and suppressed DNA repair     enzyme expression in rheumatoid arthritis. J Immunol, 170:2214-20,     2003 -   19 Christophersen N S, Helin K. Epigenetic control of embryonic stem     cell fate. J Exp Med. Oct. 25, 2010; 207(11):2287-95 -   20 Kulis M, Esteller M. DNA methylation and cancer. Adv Genet. 2010;     70:27-56 -   21 Ren J, Singh B N, Huang Q, Li Z, Gao Y, Mishra P, Hwa Y L, Li J,     Dowdy S C, Jiang S W. DNA hypermethylation as a chemotherapy target.     Cell Signal. Feb. 21, 2011. [Epub ahead of print] -   22 Turek-Plewa J, Jagodzinski P P. The role of mammalian DNA     methyltransferases in the regulation of gene expression. Cell Mol     Biol Lett. 2005; 10(4):631-47 -   23 Hollingsworth J W, Maruoka S, Boon K, Garantziotis S, Li Z,     Tomfohr J, Bailey N, Potts E N, Whitehead G, Brass differentially     methylated, Schwartz D A. In utero supplementation with methyl     donors enhances allergic airway disease in mice. J Clin Invest. 2008     October; 118(10):3462-9 -   24 Miller R L. Prenatal maternal diet affects asthma risk in     offspring. J Clin Invest. 2008. 118:3265-8 -   25 Liu C C, Fang T J, Ou T T, Wu C C, Li R N, Lin Y C, Lin C H, Tsai     W C, Liu H W, Yen J H. Global DNA methylation, DNMT1, and MBD2 in     patients with rheumatoid arthritis. Immunol Lett. Mar. 30, 2011;     135(1-2):96-9. Epub Oct. 16, 2010 -   26 Karouzakis E, Gay R E, Michel B A, Gay S, Neidhart M. DNA     hypomethylation in rheumatoid arthritis synovial fibroblasts.     Arthritis Rheum. 2009 December; 60(12):3613-22 -   27 Lee B H et al. Procainamide is a specific inhibitor of DNA     methyltransferase 1. J Biol Chem. 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All references cited herein, including but not limited to published and unpublished applications, patents, and literature references, are incorporated herein by reference in their entirety and are hereby made a part of this specification. To the extent publications and patents or patent applications incorporated by reference contradict the disclosure contained in the specification, the specification is intended to supersede and/or take precedence over any such contradictory material. 

What is claimed is:
 1. A method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising determining whether at least 2 nucleic acid loci or at least 2 genes in a sample from said subject have methylation states indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.
 2. The method of claim 1, further comprising comparing the methylation states of the at least 2 loci or at least 2 genes in the sample from said subject with the methylation states of the loci or the genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis.
 3. The method of claim 1, wherein an increase or decrease in the extent of methylation of at least 2 loci or at least 2 genes compared to the extent of methylation of the loci or genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis is indicative of the presence or absence of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or response to treatment for rheumatoid arthritis or osteoarthritis for the subject.
 4. The method of claim 1, wherein the methylation states of said at least 2 loci or at least 2 genes is determined in a cell from said subject selected from the group consisting of fibroblast, synoviocyte, fibroblast-like synoviocyte, macrophage, and peripheral blood cell.
 5. The method of claim 4, wherein the fibroblast-like synoviocyte is selected from the group consisting of rheumatoid arthritis fibroblast-like synoviocyte and osteoarthritis fibroblast-like synoviocyte
 6. The method of claim 4, wherein the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.
 7. The method of claim 1, wherein the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.
 8. The method of claim 1, wherein the at least 2 loci or at least 2 genes are selected from the group consisting of SEQ ID NO.s 1-485512, the loci listed in TABLE 6, TABLE 7, or TABLE 8, and the genes listed in TABLE
 3. 9. The method of claim 1, wherein the methylation states of at least 5 nucleic acid loci or at least 5 genes in said sample are determined.
 10. The method of claim 1, wherein the subject is a human.
 11. A method for diagnosing rheumatoid arthritis or osteoarthritis, determining a rheumatoid arthritis or osteoarthritis prognosis, or determining or predicting a response to treatment for rheumatoid arthritis or osteoarthritis in a subject comprising: determining the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample of said subject to obtain a methylation profile; and determining whether said methylation profile is indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.
 12. The method of claim 11, further comprising comparing the methylation state of the plurality of nucleic acid loci or the methylation state of the plurality of genes in the sample from said subject with the methylation state of the plurality of nucleic acid loci or the methylation state of the plurality of genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis.
 13. The method of claim 12, wherein an increase or decrease in the extent of methylation of plurality of nucleic acid loci or of the methylation state of the plurality of genes compared to the extent of methylation of the plurality of nucleic acid loci or the extent of methylation of the plurality of genes in normal tissue, tissue from a subject without said known rheumatoid arthritis or osteoarthritis prognosis, or tissue from a subject without said known response to treatment for rheumatoid arthritis or osteoarthritis is indicative of the presence or absence of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or response to treatment for rheumatoid arthritis or osteoarthritis for the subject.
 14. The method of claim 11, wherein the methylation state of said plurality of nucleic acid loci or said plurality of genes is determined in in a cell from said subject selected from the group consisting of fibroblast, synoviocyte, fibroblast-like synoviocyte, macrophage and peripheral blood cell.
 15. The method of claim 14, wherein the fibroblast-like synoviocyte is selected from the group consisting of rheumatoid arthritis fibroblast-like synoviocyte and osteoarthritis fibroblast-like synoviocyte
 16. The method of claim 14, wherein the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.
 17. The method of claim 11, wherein the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.
 18. The method of claim 11, wherein the plurality of nucleic acid loci or the plurality of genes is selected from the group consisting of SEQ ID NO.s 1-485512, the loci listed in TABLE 6, TABLE 7, or TABLE 8, and the genes listed in TABLE
 3. 19. The method of claim 11, wherein the methylation states of at least 5 nucleic acid loci or at least 5 genes in said sample are determined.
 20. The method of claim 11, wherein the subject is a human.
 21. A method of identifying a methylation profile indicative of rheumatoid arthritis, osteoarthritis, a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis comprising: determining the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample from a test subject with rheumatoid arthritis, osteoarthritis, a particular rheumatoid arthritis or osteoarthritis prognosis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis; determining the methylation states of said plurality of nucleic acid loci or said plurality of genes in a sample from a control subject without rheumatoid arthritis, without osteoarthritis, without said rheumatoid arthritis or osteoarthritis prognosis or without said response to treatment for rheumatoid arthritis or osteoarthritis; and identifying loci or genes which are hypermethylated or hypomethylated in said sample from said test subject relative to said sample from said control subject to identify said methylation profile indicative of rheumatoid arthritis, osteoarthritis a rheumatoid arthritis or osteoarthritis prognosis, or a response to treatment for rheumatoid arthritis or osteoarthritis.
 22. The method of claim 21, further comprising storing data representing said loci or said genes which are hypermethylated or hypomethylated in said sample from said test subject relative to said sample from said control subject on a non-transitory computer readable medium.
 23. The method of claim 22, further comprising comparing the methylation states of a plurality of nucleic acid loci or the methylation states of a plurality of genes in a sample from a test subject with rheumatoid arthritis, osteoarthritis, a particular rheumatoid arthritis or osteoarthritis prognosis, or a particular response to treatment for rheumatoid arthritis or osteoarthritis with the methylation states of said plurality of nucleic acid loci or the methylation states of said plurality of genes in a sample from a control subject without rheumatoid arthritis, without osteoarthritis, without said rheumatoid arthritis or osteoarthritis prognosis or without said response to treatment for rheumatoid arthritis or osteoarthritis.
 24. The method of claim 21, wherein the methylation state of said plurality of nucleic acid loci or said plurality of genes in a sample from said test subject or said control subject is determined in a cell from said subject or said control subject selected from the group consisting of fibroblast, synoviocyte, fibroblast-like synoviocyte, macrophage, and peripheral blood cell.
 25. The method of claim 24, wherein the fibroblast-like synoviocyte is selected from the group consisting of rheumatoid arthritis fibroblast-like synoviocyte and osteoarthritis fibroblast-like synoviocyte
 26. The method of claim 24, wherein the peripheral blood cell is selected from the group consisting of white blood cell, neutrophil, eosinophil, basophil, lymphocyte, B cell, plasma cell, T cell, natural killer cell, monocyte, and dendritic cell.
 27. The method of claim 21, wherein the sample is selected from the group consisting of a tissue sample, a frozen tissue sample, a biopsy specimen, a surgical specimen, a cytological specimen, whole blood, bone marrow, cerebral spinal fluid, peritoneal fluid, lymph fluid, serum, plasma, urine, stool, and nipple aspirate.
 28. The method of claim 21, wherein the methylation states of at least 5 nucleic acid loci or at least 5 genes are determined.
 29. The method of claim 21, wherein the subject is a human.
 30. A method of ameliorating rheumatoid arthritis or osteoarthritis comprising: evaluating the methylation status of a plurality of human nucleic acid loci in a nucleic acid sample from a human subject having symptoms of rheumatoid arthritis or osteoarthritis, wherein said loci comprise at least 5 loci or at least 5 genes selected from the group consisting of SEQ ID NO.s 1-485512, the loci listed in TABLE 6, TABLE 7, or TABLE 8, and the genes listed in TABLE 3; and administering a treatment for rheumatoid arthritis or osteoarthritis if said at least 5 loci or said at least 5 genes have a methylation status indicative of rheumatoid arthritis or osteoarthritis. 